Caching Framework for a Multi-Tenant Identity and Data Security Management Cloud Service

ABSTRACT

A caching framework for a multi-tenant cloud-based system includes a plurality of microservices, a global cache that implements a global namespace, and a plurality of tenant caches, each tenant cache corresponding to a different tenant of the multi-tenant cloud-based system. The framework further includes a common module corresponding to each of the microservices and comprising a cache application programming interface (API), and a cache module comprising a service provider interface (SPI) adapted to connect to a distributed remote cache.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims priority of U.S. patent application Ser. No. 15/661,014, filed on Jul. 27, 2017, U.S. Provisional Patent Application Ser. No. 62/371,336, filed on Aug. 5, 2016, U.S. Provisional Patent Application Ser. No. 62/376,069, filed on Aug. 17, 2016, U.S. Provisional Patent Application Ser. No. 62/395,463, filed on Sep. 16, 2016, and U.S. Provisional Patent Application Ser. No. 62/385,339, filed on Sep. 9, 2016. The disclosures of each of the foregoing applications are hereby incorporated by reference.

FIELD

One embodiment is directed generally to identity management, and in particular, to identity management in a cloud system.

BACKGROUND INFORMATION

Generally, the use of cloud-based applications (e.g., enterprise public cloud applications, third-party cloud applications, etc.) is soaring, with access coming from a variety of devices (e.g., desktop and mobile devices) and a variety of users (e.g., employees, partners, customers, etc.). The abundant diversity and accessibility of cloud-based applications has led identity management and access security to become a central concern. Typical security concerns in a cloud environment are unauthorized access, account hijacking, malicious insiders, etc. Accordingly, there is a need for secure access to cloud-based applications, or applications located anywhere, regardless of from what device type or by what user type the applications are accessed.

SUMMARY

Embodiments are directed to a caching framework for a multi-tenant cloud-based system includes a plurality of microservices, a global cache that implements a global namespace, and a plurality of tenant caches, each tenant cache corresponding to a different tenant of the multi-tenant cloud-based system. The framework further includes a common module corresponding to each of the microservices and comprising a cache application programming interface (API), and a cache module comprising a service provider interface (SPI) adapted to connect to a distributed remote cache.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1-5 are block diagrams of example embodiments that provide cloud-based identity management.

FIG. 6 is a block diagram providing a system view of an embodiment.

FIG. 6A is a block diagram providing a functional view of an embodiment.

FIG. 7 is a block diagram of an embodiment that implements Cloud Gate.

FIG. 8 illustrates an example system that implements multiple tenancies in one embodiment.

FIG. 9 is a block diagram of a network view of an embodiment.

FIG. 10 is a block diagram of a system architecture view of single sign on (“SSO”) functionality in one embodiment.

FIG. 11 is a message sequence flow of SSO functionality in one embodiment.

FIG. 12 illustrates an example of a distributed data grid in one embodiment.

FIG. 13 is an example block diagram illustrating caching functionality in one embodiment.

FIG. 14 is an example block diagram illustrating the functionality of a remote application programming interface (“API”) proxy in one embodiment.

FIG. 15 is an example block diagram illustrating code categorization for caching functionality in one embodiment.

FIG. 16 is an example block diagram illustrating a functional view of caching functionality in one embodiment.

FIG. 17 is a flow diagram of identity and access management functionality in accordance with an embodiment.

DETAILED DESCRIPTION

One embodiment provides a caching framework for stateless microservices in a multi-tenant identity and data security cloud service. The embodiment implements a near cache in the virtual machine of each microservice and a remote cache provided by a distributed data grid. One embodiment implements a remote application programming interface (“API”) proxy in each microservice except for an administration microservice. The remote API proxy emulates the administration microservice and therefore allows the other microservices to retrieve cached data without needing to call the administration microservice every time a resource is requested. By reducing the load on the administration microservice and removing the network hops needed to reach the administration microservice, embodiments provide improved performance.

Embodiments provide an identity cloud service that implements a microservices based architecture and provides multi-tenant identity and data security management and secure access to cloud-based applications. Embodiments support secure access for hybrid cloud deployments (i.e., cloud deployments which include a combination of a public cloud and a private cloud). Embodiments protect applications and data both in the cloud and on-premise. Embodiments support multi-channel access via web, mobile, and APIs. Embodiments manage access for different users, such as customers, partners, and employees. Embodiments manage, control, and audit access across the cloud as well as on-premise. Embodiments integrate with new and existing applications and identities. Embodiments are horizontally scalable.

One embodiment is a system that implements a number of microservices in a stateless middle tier environment to provide cloud-based multi-tenant identity and access management services. In one embodiment, each requested identity management service is broken into real-time and near-real-time tasks. The real-time tasks are handled by a microservice in the middle tier, while the near-real-time tasks are offloaded to a message queue. Embodiments implement access tokens that are consumed by a routing tier and a middle tier to enforce a security model for accessing the microservices. Accordingly, embodiments provide a cloud-scale Identity and Access Management (“IAM”) platform based on a multi-tenant, microservices architecture.

One embodiment provides an identity cloud service that enables organizations to rapidly develop fast, reliable, and secure services for their new business initiatives. In one embodiment, the identity cloud service provides a number of core services, each of which solving a unique challenge faced by many enterprises. In one embodiment, the identity cloud service supports administrators in, for example, initial on-boarding/importing of users, importing groups with user members, creating/updating/disabling/enabling/deleting users, assigning/un-assigning users into/from groups, creating/updating/deleting groups, resetting passwords, managing policies, sending activation, etc. The identity cloud service also supports end users in, for example, modifying profiles, setting primary/recovery emails, verifying emails, unlocking their accounts, changing passwords, recovering passwords in case of forgotten password, etc.

Unified Security of Access

One embodiment protects applications and data in a cloud environment as well as in an on-premise environment. The embodiment secures access to any application from any device by anyone. The embodiment provides protection across both environments since inconsistencies in security between the two environments may result in higher risks. For example, such inconsistencies may cause a sales person to continue having access to their Customer Relationship Management (“CRM”) account even after they have defected to the competition. Accordingly, embodiments extend the security controls provisioned in the on-premise environment into the cloud environment. For example, if a person leaves a company, embodiments ensure that their accounts are disabled both on-premise and in the cloud.

Generally, users may access applications and/or data through many different channels such as web browsers, desktops, mobile phones, tablets, smart watches, other wearables, etc. Accordingly, one embodiment provides secured access across all these channels. For example, a user may use their mobile phone to complete a transaction they started on their desktop.

One embodiment further manages access for various users such as customers, partners, employees, etc. Generally, applications and/or data may be accessed not just by employees but by customers or third parties. Although many known systems take security measures when onboarding employees, they generally do not take the same level of security measures when giving access to customers, third parties, partners, etc., resulting in the possibility of security breaches by parties that are not properly managed. However, embodiments ensure that sufficient security measures are provided for access of each type of user and not just employees.

Identity Cloud Service

Embodiments provide an Identity Cloud Service (“IDCS”) that is a multi-tenant, cloud-scale, IAM platform. IDCS provides authentication, authorization, auditing, and federation. IDCS manages access to custom applications and services running on the public cloud, and on-premise systems. In an alternative or additional embodiment, IDCS may also manage access to public cloud services. For example, IDCS can be used to provide Single Sign On (“SSO”) functionality across such variety of services/applications/systems.

Embodiments are based on a multi-tenant, microservices architecture for designing, building, and delivering cloud-scale software services. Multi-tenancy refers to having one physical implementation of a service securely supporting multiple customers buying that service. A service is a software functionality or a set of software functionalities (such as the retrieval of specified information or the execution of a set of operations) that can be reused by different clients for different purposes, together with the policies that control its usage (e.g., based on the identity of the client requesting the service). In one embodiment, a service is a mechanism to enable access to one or more capabilities, where the access is provided using a prescribed interface and is exercised consistent with constraints and policies as specified by the service description.

In one embodiment, a microservice is an independently deployable service. In one embodiment, the term microservice contemplates a software architecture design pattern in which complex applications are composed of small, independent processes communicating with each other using language-agnostic APIs. In one embodiment, microservices are small, highly decoupled services and each may focus on doing a small task. In one embodiment, the microservice architectural style is an approach to developing a single application as a suite of small services, each running in its own process and communicating with lightweight mechanisms (e.g., an Hypertext Transfer Protocol (“HTTP”) resource API). In one embodiment, microservices are easier to replace relative to a monolithic service that performs all or many of the same functions. Moreover, each of the microservices may be updated without adversely affecting the other microservices. In contrast, updates to one portion of a monolithic service may undesirably or unintentionally negatively affect the other portions of the monolithic service. In one embodiment, microservices may be beneficially organized around their capabilities. In one embodiment, the startup time for each of a collection of microservices is much less than the startup time for a single application that collectively performs all the services of those microservices. In some embodiments, the startup time for each of such microservices is about one second or less, while the startup time of such single application may be about a minute, several minutes, or longer.

In one embodiment, microservices architecture refers to a specialization (i.e., separation of tasks within a system) and implementation approach for service oriented architectures (“SOAs”) to build flexible, independently deployable software systems. Services in a microservices architecture are processes that communicate with each other over a network in order to fulfill a goal. In one embodiment, these services use technology-agnostic protocols. In one embodiment, the services have a small granularity and use lightweight protocols. In one embodiment, the services are independently deployable. By distributing functionalities of a system into different small services, the cohesion of the system is enhanced and the coupling of the system is decreased. This makes it easier to change the system and add functions and qualities to the system at any time. It also allows the architecture of an individual service to emerge through continuous refactoring, and hence reduces the need for a big up-front design and allows for releasing software early and continuously.

In one embodiment, in the microservices architecture, an application is developed as a collection of services, and each service runs a respective process and uses a lightweight protocol to communicate (e.g., a unique API for each microservice). In the microservices architecture, decomposition of a software into individual services/capabilities can be performed at different levels of granularity depending on the service to be provided. A service is a runtime component/process. Each microservice is a self-contained module that can talk to other modules/microservices. Each microservice has an unnamed universal port that can be contacted by others. In one embodiment, the unnamed universal port of a microservice is a standard communication channel that the microservice exposes by convention (e.g., as a conventional HTTP port) and that allows any other module/microservice within the same service to talk to it. A microservice or any other self-contained functional module can be generically referred to as a “service”.

Embodiments provide multi-tenant identity management services. Embodiments are based on open standards to ensure ease of integration with various applications, delivering IAM capabilities through standards-based services.

Embodiments manage the lifecycle of user identities which entails the determination and enforcement of what an identity can access, who can be given such access, who can manage such access, etc. Embodiments run the identity management workload in the cloud and support security functionality for applications that are not necessarily in the cloud. The identity management services provided by the embodiments may be purchased from the cloud. For example, an enterprise may purchase such services from the cloud to manage their employees' access to their applications.

Embodiments provide system security, massive scalability, end user usability, and application interoperability. Embodiments address the growth of the cloud and the use of identity services by customers. The microservices based foundation addresses horizontal scalability requirements, while careful orchestration of the services addresses the functional requirements. Achieving both goals requires decomposition (wherever possible) of the business logic to achieve statelessness with eventual consistency, while much of the operational logic not subject to real-time processing is shifted to near-real-time by offloading to a highly scalable asynchronous event management system with guaranteed delivery and processing. Embodiments are fully multi-tenant from the web tier to the data tier in order to realize cost efficiencies and ease of system administration.

Embodiments are based on industry standards (e.g., Open ID Connect, OAuth2, Security Assertion Markup Language 2 (“SAML2”), System for Cross-domain Identity Management (“SCIM”), Representational State Transfer (“REST”), etc.) for ease of integration with various applications. One embodiment provides a cloud-scale API platform and implements horizontally scalable microservices for elastic scalability. The embodiment leverages cloud principles and provides a multi-tenant architecture with per-tenant data separation. The embodiment further provides per-tenant customization via tenant self-service. The embodiment is available via APIs for on-demand integration with other identity services, and provides continuous feature release.

One embodiment provides interoperability and leverages investments in identity management (“IDM”) functionality in the cloud and on-premise. The embodiment provides automated identity synchronization from on-premise Lightweight Directory Access Protocol (“LDAP”) data to cloud data and vice versa. The embodiment provides a SCIM identity bus between the cloud and the enterprise, and allows for different options for hybrid cloud deployments (e.g., identity federation and/or synchronization, SSO agents, user provisioning connectors, etc.).

Accordingly, one embodiment is a system that implements a number of microservices in a stateless middle tier to provide cloud-based multi-tenant identity and access management services. In one embodiment, each requested identity management service is broken into real-time and near-real-time tasks. The real-time tasks are handled by a microservice in the middle tier, while the near-real-time tasks are offloaded to a message queue. Embodiments implement tokens that are consumed by a routing tier to enforce a security model for accessing the microservices. Accordingly, embodiments provide a cloud-scale IAM platform based on a multi-tenant, microservices architecture.

Generally, known systems provide siloed access to applications provided by different environments, e.g., enterprise cloud applications, partner cloud applications, third-party cloud applications, and customer applications. Such siloed access may require multiple passwords, different password policies, different account provisioning and de-provisioning schemes, disparate audit, etc. However, one embodiment implements IDCS to provide unified IAM functionality over such applications. FIG. 1 is a block diagram 100 of an example embodiment with IDCS 118, providing a unified identity platform 126 for onboarding users and applications. The embodiment provides seamless user experience across various applications such as enterprise cloud applications 102, partner cloud applications 104, third-party cloud applications 110, and customer applications 112. Applications 102, 104, 110, 112 may be accessed through different channels, for example, by a mobile phone user 108 via a mobile phone 106, by a desktop computer user 116 via a browser 114, etc. A web browser (commonly referred to as a browser) is a software application for retrieving, presenting, and traversing information resources on the World Wide Web. Examples of web browsers are Mozilla Firefox®, Google Chrome®, Microsoft Internet Explorer®, and Apple Safari®.

IDCS 118 provides a unified view 124 of a user's applications, a unified secure credential across devices and applications (via identity platform 126), and a unified way of administration (via an admin console 122). IDCS services may be obtained by calling IDCS APIs 142. Such services may include, for example, login/SSO services 128 (e.g., OpenID Connect), federation services 130 (e.g., SAML), token services 132 (e.g., OAuth), directory services 134 (e.g., SCIM), provisioning services 136 (e.g., SCIM or Any Transport over Multiprotocol (“AToM”)), event services 138 (e.g., REST), and role-based access control (“RBAC”) services 140 (e.g., SCIM). IDCS 118 may further provide reports and dashboards 120 related to the offered services.

Integration Tools

Generally, it is common for large corporations to have an IAM system in place to secure access to their on-premise applications. Business practices are usually matured and standardized around an in-house IAM system such as “Oracle IAM Suite” from Oracle Corp. Even small to medium organizations usually have their business processes designed around managing user access through a simple directory solution such as Microsoft Active Directory (“AD”). To enable on-premise integration, embodiments provide tools that allow customers to integrate their applications with IDCS.

FIG. 2 is a block diagram 200 of an example embodiment with IDCS 202 in a cloud environment 208, providing integration with an AD 204 that is on-premise 206. The embodiment provides seamless user experience across all applications including on-premise and third-party applications, for example, on-premise applications 218 and various applications/services in cloud 208 such as cloud services 210, cloud applications 212, partner applications 214, and customer applications 216. Cloud applications 212 may include, for example, Human Capital Management (“HCM”), CRM, talent acquisition (e.g., Oracle Taleo cloud service from Oracle Corp.), Configure Price and Quote (“CPQ”), etc. Cloud services 210 may include, for example, Platform as a Service (“PaaS”), Java, database, business intelligence (“BI”), documents, etc.

Applications 210, 212, 214, 216, 218, may be accessed through different channels, for example, by a mobile phone user 220 via a mobile phone 222, by a desktop computer user 224 via a browser 226, etc. The embodiment provides automated identity synchronization from on-premise AD data to cloud data via a SCIM identity bus 234 between cloud 208 and the enterprise 206. The embodiment further provides a SAML bus 228 for federating authentication from cloud 208 to on-premise AD 204 (e.g., using passwords 232).

Generally, an identity bus is a service bus for identity related services. A service bus provides a platform for communicating messages from one system to another system. It is a controlled mechanism for exchanging information between trusted systems, for example, in a service oriented architecture (“SOA”). An identity bus is a logical bus built according to standard HTTP based mechanisms such as web service, web server proxies, etc. The communication in an identity bus may be performed according to a respective protocol (e.g., SCIM, SAML, OpenID Connect, etc.). For example, a SAML bus is an HTTP based connection between two systems for communicating messages for SAML services. Similarly, a SCIM bus is used to communicate SCIM messages according to the SCIM protocol.

The embodiment of FIG. 2 implements an identity (“ID”) bridge 230 that is a small binary (e.g., 1 MB in size) that can be downloaded and installed on-premise 206 alongside a customer's AD 204. ID Bridge 230 listens to users and groups (e.g., groups of users) from the organizational units (“OUs”) chosen by the customer and synchronizes those users to cloud 208. In one embodiment, users' passwords 232 are not synchronized to cloud 208. Customers can manage application access for users by mapping IDCS users' groups to cloud applications managed in IDCS 208. Whenever the users' group membership is changed on-premise 206, their corresponding cloud application access changes automatically.

For example, an employee moving from engineering to sales can get near instantaneous access to the sales cloud and lose access to the developer cloud. When this change is reflected in on-premise AD 204, cloud application access change is accomplished in near-real-time. Similarly, access to cloud applications managed in IDCS 208 is revoked for users leaving the company. For full automation, customers may set up SSO between on-premise AD 204 and IDCS 208 through, e.g., AD federation service (“AD/FS”, or some other mechanism that implements SAML federation) so that end users can get access to cloud applications 210, 212, 214, 216, and on-premise applications 218 with a single corporate password 332.

FIG. 3 is a block diagram 300 of an example embodiment that includes the same components 202, 206, 208, 210, 212, 214, 216, 218, 220, 222, 224, 226, 228, 234 as in FIG. 2. However, in the embodiment of FIG. 3, IDCS 202 provides integration with an on-premise IDM 304 such as Oracle IDM. Oracle IDM 304 is a software suite from Oracle Corp. for providing IAM functionality. The embodiment provides seamless user experience across all applications including on-premise and third-party applications. The embodiment provisions user identities from on-premise IDM 304 to IDCS 208 via SCIM identity bus 234 between cloud 202 and enterprise 206. The embodiment further provides SAML bus 228 (or an OpenID Connect bus) for federating authentication from cloud 208 to on-premise 206.

In the embodiment of FIG. 3, an Oracle Identity Manager (“OIM”) Connector 302 from Oracle Corp., and an Oracle Access Manager (“OAM”) federation module 306 from Oracle Corp., are implemented as extension modules of Oracle IDM 304. A connector is a module that has physical awareness about how to talk to a system. OIM is an application configured to manage user identities (e.g., manage user accounts in different systems based on what a user should and should not have access to). OAM is a security application that provides access management functionality such as web SSO; identity context, authentication and authorization; policy administration; testing; logging; auditing; etc. OAM has built-in support for SAML. If a user has an account in IDCS 202, OIM connector 302 and OAM federation 306 can be used with Oracle IDM 304 to create/delete that account and manage access from that account.

FIG. 4 is a block diagram 400 of an example embodiment that includes the same components 202, 206, 208, 210, 212, 214, 216, 218, 220, 222, 224, 226, 234 as in FIGS. 2 and 3. However, in the embodiment of FIG. 4, IDCS 202 provides functionality to extend cloud identities to on-premise applications 218. The embodiment provides seamless view of the identity across all applications including on-premise and third-party applications. In the embodiment of FIG. 4, SCIM identity bus 234 is used to synchronize data in IDCS 202 with on-premise LDAP data called “Cloud Cache” 402. Cloud Cache 402 is disclosed in more detail below.

Generally, an application that is configured to communicate based on LDAP needs an LDAP connection. An LDAP connection may not be established by such application through a URL (unlike, e.g., “www.google.com” that makes a connection to Google) since the LDAP needs to be on a local network. In the embodiment of FIG. 4, an LDAP-based application 218 makes a connection to Cloud Cache 402, and Cloud Cache 402 establishes a connection to IDCS 202 and then pulls data from IDCS 202 as it is being requested. The communication between IDCS 202 and Cloud Cache 402 may be implemented according to the SCIM protocol. For example, Cloud Cache 402 may use SCIM bus 234 to send a SCIM request to IDCS 202 and receive corresponding data in return.

Generally, fully implementing an application includes building a consumer portal, running marketing campaigns on the external user population, supporting web and mobile channels, and dealing with user authentication, sessions, user profiles, user groups, application roles, password policies, self-service/registration, social integration, identity federation, etc. Generally, application developers are not identity/security experts. Therefore, on-demand identity management services are desired.

FIG. 5 is a block diagram 500 of an example embodiment that includes the same components 202, 220, 222, 224, 226, 234, 402, as in FIGS. 2-4. However, in the embodiment of FIG. 5, IDCS 202 provides secure identity management on demand. The embodiment provides on demand integration with identity services of IDCS 202 (e.g., based on standards such as OpenID Connect, OAuth2, SAML2, or SCIM). Applications 505 (which may be on-premise, in a public cloud, or in a private cloud) may call identity service APIs 504 in IDCS 202. The services provided by IDCS 202 may include, for example, self-service registration 506, password management 508, user profile management 510, user authentication 512, token management 514, social integration 516, etc.

In this embodiment, SCIM identity bus 234 is used to synchronize data in IDCS 202 with data in on-premise LDAP Cloud Cache 402. Further, a “Cloud Gate” 502 running on a web server/proxy (e.g., NGINX, Apache, etc.) may be used by applications 505 to obtain user web SSO and REST API security from IDCS 202. Cloud Gate 502 is a component that secures access to multi-tenant IDCS microservices by ensuring that client applications provide valid access tokens, and/or users successfully authenticate in order to establish SSO sessions. Cloud Gate 502 is further disclosed below. Cloud Gate 502 (enforcement point similar to webgate/webagent) enables applications running behind supported web servers to participate in SSO.

One embodiment provides SSO and cloud SSO functionality. A general point of entry for both on-premise IAM and IDCS in many organizations is SSO. Cloud SSO enables users to access multiple cloud resources with a single user sign-in. Often, organizations will want to federate their on-premise identities. Accordingly, embodiments utilize open standards to allow for integration with existing SSO to preserve and extend investment (e.g., until a complete, eventual transition to an identity cloud service approach is made).

One embodiment may provide the following functionalities:

maintain an identity store to track user accounts, ownership, access, and permissions that have been authorized,

integrate with workflow to facilitate various approvals (e.g., management, IT, human resources, legal, and compliance) needed for applications access,

provision SaaS user accounts for selective devices (e.g., mobile and personal computer (“PC”)) with access to user portal containing many private and public cloud resources, and

facilitate periodic management attestation review for compliance with regulations and current job responsibilities.

In addition to these functions, embodiments may further provide:

cloud account provisioning to manage account life cycle in cloud applications,

more robust multifactor authentication (“MFA”) integration,

extensive mobile security capabilities, and

dynamic authentication options.

One embodiment provides adaptive authentication and MFA. Generally, passwords and challenge questions have been seen as inadequate and susceptible to common attacks such as phishing. Most business entities today are looking at some form of MFA to reduce risk. To be successfully deployed, however, solutions need to be easily provisioned, maintained, and understood by the end user, as end users usually resist anything that interferes with their digital experience. Companies are looking for ways to securely incorporate bring your own device (“BYOD”), social identities, remote users, customers, and contractors, while making MFA an almost transparent component of a seamless user access experience. Within an MFA deployment, industry standards such as OAuth and OpenID Connect are essential to ensure integration of existing multifactor solutions and the incorporation of newer, adaptive authentication technology. Accordingly, embodiments define dynamic (or adaptive) authentication as the evaluation of available information (i.e., IP address, location, time of day, and biometrics) to prove an identity after a user session has been initiated. With the appropriate standards (e.g., open authentication (“OATH”) and fast identity online (“FIDO”)) integration and extensible identity management framework, embodiments provide MFA solutions that can be adopted, upgraded, and integrated easily within an IT organization as part of an end-to-end secure IAM deployment. When considering MFA and adaptive policies, organizations must implement consistent policies across on-premise and cloud resources, which in a hybrid IDCS and on-premise IAM environment requires integration between systems.

One embodiment provides user provisioning and certification. Generally, the fundamental function of an IAM solution is to enable and support the entire user provisioning life cycle. This includes providing users with the application access appropriate for their identity and role within the organization, certifying that they have the correct ongoing access permissions (e.g., as their role or the tasks or applications used within their role change over time), and promptly de-provisioning them as their departure from the organization may require. This is important not only for meeting various compliance requirements but also because inappropriate insider access is a major source of security breaches and attacks. An automated user provisioning capability within an identity cloud solution can be important not only in its own right but also as part of a hybrid IAM solution whereby IDCS provisioning may provide greater flexibility than an on-premise solution for transitions as a company downsizes, upsizes, merges, or looks to integrate existing systems with IaaS/PaaS/SaaS environments. An IDCS approach can save time and effort in one-off upgrades and ensure appropriate integration among necessary departments, divisions, and systems. The need to scale this technology often sneaks up on corporations, and the ability to deliver a scalable IDCS capability immediately across the enterprise can provide benefits in flexibility, cost, and control.

Generally, an employee is granted additional privileges (i.e., “privilege creep”) over the years as her/his job changes. Companies that are lightly regulated generally lack an “attestation” process that requires managers to regularly audit their employees' privileges (e.g., access to networks, servers, applications, and data) to halt or slow the privilege creep that results in over-privileged accounts. Accordingly, one embodiment may provide a regularly conducted (at least once a year) attestation process. Further, with mergers and acquisitions, the need for these tools and services increases exponentially as users are on SaaS systems, on-premise, span different departments, and/or are being de-provisioned or re-allocated. The move to cloud can further confuse this situation, and things can quickly escalate beyond existing, often manually managed, certification methods. Accordingly, one embodiment automates these functions and applies sophisticated analytics to user profiles, access history, provisioning/de-provisioning, and fine-grained entitlements.

One embodiment provides identity analytics. Generally, the ability to integrate identity analytics with the IAM engine for comprehensive certification and attestation can be critical to securing an organization's risk profile. Properly deployed identity analytics can demand total internal policy enforcement. Identity analytics that provide a unified single management view across cloud and on-premise are much needed in a proactive governance, risk, and compliance (“GRC”) enterprise environment, and can aid in providing a closed-loop process for reducing risk and meeting compliance regulations. Accordingly, one embodiment provides identity analytics that are easily customizable by the client to accommodate specific industry demands and government regulations for reports and analysis required by managers, executives, and auditors.

One embodiment provides self-service and access request functionality to improve the experience and efficiency of the end user and to reduce costs from help desk calls. Generally, while a number of companies deploy on-premise self-service access request for their employees, many have not extended these systems adequately outside the formal corporate walls. Beyond employee use, a positive digital customer experience increases business credibility and ultimately contributes to revenue increase, and companies not only save on customer help desk calls and costs but also improve customer satisfaction. Accordingly, one embodiment provides an identity cloud service environment that is based on open standards and seamlessly integrates with existing access control software and MFA mechanisms when necessary. The SaaS delivery model saves time and effort formerly devoted to systems upgrades and maintenance, freeing professional IT staff to focus on more core business applications.

One embodiment provides privileged account management (“PAM”). Generally, every organization, whether using SaaS, PaaS, IaaS, or on-premise applications, is vulnerable to unauthorized privileged account abuse by insiders with super-user access credentials such as system administrators, executives, HR officers, contractors, systems integrators, etc. Moreover, outside threats typically first breach a low-level user account to eventually reach and exploit privileged user access controls within the enterprise system. Accordingly, one embodiment provides PAM to prevent such unauthorized insider account use. The main component of a PAM solution is a password vault which may be delivered in various ways, e.g., as software to be installed on an enterprise server, as a virtual appliance also on an enterprise server, as a packaged hardware/software appliance, or as part of a cloud service. PAM functionality is similar to a physical safe used to store passwords kept in an envelope and changed periodically, with a manifest for signing them in and out. One embodiment allows for a password checkout as well as setting time limits, forcing periodic changes, automatically tracking checkout, and reporting on all activities. One embodiment provides a way to connect directly through to a requested resource without the user ever knowing the password. This capability also paves the way for session management and additional functionality.

Generally, most cloud services utilize APIs and administrative interfaces, which provide opportunities for infiltrators to circumvent security. Accordingly, one embodiment accounts for these holes in PAM practices as the move to the cloud presents new challenges for PAM. Many small to medium sized businesses now administer their own SaaS systems (e.g., Office 365), while larger companies increasingly have individual business units spinning up their own SaaS and IaaS services. These customers find themselves with PAM capabilities within the identity cloud service solutions or from their IaaS/PaaS provider but with little experience in handling this responsibility. Moreover, in some cases, many different geographically dispersed business units are trying to segregate administrative responsibilities for the same SaaS applications. Accordingly, one embodiment allows customers in these situations to link existing PAM into the overall identity framework of the identity cloud service and move toward greater security and compliance with the assurance of scaling to cloud load requirements as business needs dictate.

API Platform

Embodiments provide an API platform that exposes a collection of capabilities as services. The APIs are aggregated into microservices, and each microservice provides one or more capabilities by exposing one or more APIs. That is, each microservice may expose different types of APIs. In one embodiment, each microservice communicates only through its APIs. In one embodiment, each API may be a microservice. In one embodiment, multiple APIs are aggregated into a service based on a target capability to be provided by that service (e.g., OAuth, SAML, Admin, etc.). As a result, similar APIs are not exposed as separate runtime processes. The APIs are what is made available to a service consumer to use the services provided by IDCS.

Generally, in the web environment of IDCS, a URL includes three parts: a host, a microservice, and a resource (e.g., host/microservice/resource). In one embodiment, the microservice is characterized by having a specific URL prefix, e.g., “host/oauth/v1” where the actual microservice is “oauth/v1”, and under “oauth/v1” there are multiple APIs, e.g., an API to request tokens: “host/oauth/v1/token”, an API to authenticate a user: “host/oauth/v1/authorize”, etc. That is, the URL implements a microservice, and the resource portion of the URL implements an API. Accordingly, multiple APIs are aggregated under the same microservice, and each request includes a call to an API that identifies an identity management service (e.g., request a token, authenticate a user, etc.) and a microservice (e.g., OAuth) configured to perform the identity management service.

In one embodiment, the host portion of the URL identifies a tenant (e.g., https://tenant3.identity.oraclecloud.com:/oauth/v1/token”). In one embodiment, the host portion of the URL identifies a tenancy of a resource related to the request.

Configuring applications that integrate with external services with the necessary endpoints and keeping that configuration up to date is typically a challenge. To meet this challenge, embodiments expose a public discovery API at a well-known location from where applications can discover the information about IDCS they need in order to consume IDCS APIs. In one embodiment, two discovery documents are supported: IDCS Configuration (which includes IDCS, SAML, SCIM, OAuth, and OpenID Connect configuration, at e.g., <IDCS-URL>/.well-known/idcs-configuration), and Industry-standard OpenID Connect Configuration (at, e.g., <IDCS-URL>/.well-known/openid-configuration). Applications can retrieve discovery documents by being configured with a single IDCS URL.

FIG. 6 is a block diagram providing a system view 600 of IDCS in one embodiment. In FIG. 6, any one of a variety of applications/services 602 may make HTTP calls to IDCS APIs to use IDCS services. Examples of such applications/services 602 are web applications, native applications (e.g., applications that are built to run on a specific operating system, such as Windows applications, iOS applications, Android applications, etc.), web services, customer applications, partner applications, or any services provided by a public cloud, such as Software as a Service (“SaaS”), PaaS, and Infrastructure as a Service (“IaaS”).

In one embodiment, the HTTP requests of applications/services 602 that require IDCS services go through an Oracle Public Cloud BIG-IP appliance 604 and an IDCS BIG-IP appliance 606 (or similar technologies such as a Load Balancer, or a component called a Cloud Load Balancer as a Service (“LBaaS”) that implements appropriate security rules to protect the traffic). However, the requests can be received in any manner. At IDCS BIG-IP appliance 606 (or, as applicable, a similar technology such as a Load Balancer or a Cloud LBaaS), a cloud provisioning engine 608 performs tenant and service orchestration. In one embodiment, cloud provisioning engine 608 manages internal security artifacts associated with a new tenant being on-boarded into the cloud or a new service instance purchased by a customer.

The HTTP requests are then received by an IDCS web routing tier 610 that implements a security gate (i.e., Cloud Gate) and provides service routing and microservices registration and discovery 612. Depending on the service requested, the HTTP request is forwarded to an IDCS microservice in the IDCS middle tier 614. IDCS microservices process external and internal HTTP requests. IDCS microservices implement platform services and infrastructure services. IDCS platform services are separately deployed Java-based runtime services implementing the business of IDCS. IDCS infrastructure services are separately deployed runtime services providing infrastructure support for IDCS. IDCS further includes infrastructure libraries that are common code packaged as shared libraries used by IDCS services and shared libraries. Infrastructure services and libraries provide supporting capabilities as required by platform services for implementing their functionality.

Platform Services

In one embodiment, IDCS supports standard authentication protocols, hence IDCS microservices include platform services such as Open ID Connect, OAuth, SAML2, System for Cross-domain Identity Management++(“SCIM++”), etc.

The OpenID Connect platform service implements standard OpenID Connect Login/Logout flows. Interactive web-based and native applications leverage standard browser-based Open ID Connect flow to request user authentication, receiving standard identity tokens that are JavaScript Object Notation (“JSON”) Web Tokens (“JWTs”) conveying the user's authenticated identity. Internally, the runtime authentication model is stateless, maintaining the user's authentication/session state in the form of a host HTTP cookie (including the JWT identity token). The authentication interaction initiated via the Open ID Connect protocol is delegated to a trusted SSO service that implements the user login/logout ceremonies for local and federated logins. Further details of this functionality are disclosed below with reference to FIGS. 10 and 11. In one embodiment, Open ID Connect functionality is implemented according to, for example, OpenID Foundation standards.

The OAuth2 platform service provides token authorization services. It provides a rich API infrastructure for creating and validating access tokens conveying user rights to make API calls. It supports a range of useful token grant types, enabling customers to securely connect clients to their services. It implements standard 2-legged and 3-legged OAuth2 token grant types. Support for OpenID Connect (“OIDC”) enables compliant applications (OIDC relaying parties (“RP”s)) to integrate with IDCS as the identity provider (OIDC OpenID provider (“OP”)). Similarly, the integration of IDCS as OIDC RP with social OIDC OP (e.g., Facebook, Google, etc.) enables customers to allow social identities policy-based access to applications. In one embodiment, OAuth functionality is implemented according to, for example, Internet Engineering Task Force (“IETF”), Request for Comments (“RFC”) 6749.

The SAML2 platform service provides identity federation services. It enables customers to set up federation agreements with their partners based on SAML identity provider (“IDP”) and SAML service provider (“SP”) relationship models. In one embodiment, the SAML2 platform service implements standard SAML2 Browser POST Login and Logout Profiles. In one embodiment, SAML functionality is implemented according to, for example, IETF, RFC 7522.

SCIM is an open standard for automating the exchange of user identity information between identity domains or information technology (“IT”) systems, as provided by, e.g., IETF, RFCs 7642, 7643, 7644. The SCIM++ platform service provides identity administration services and enables customers to access IDP features of IDCS. The administration services expose a set of stateless REST interfaces (i.e., APIs) that cover identity lifecycle, password management, group management, etc., exposing such artifacts as web-accessible resources.

All IDCS configuration artifacts are resources, and the APIs of the administration services allow for managing IDCS resources (e.g., users, roles, password policies, applications, SAML/OIDC identity providers, SAML service providers, keys, certifications, notification templates, etc.). Administration services leverage and extend the SCIM standard to implement schema-based REST APIs for Create, Read, Update, Delete, and Query (“CRUDQ”) operations on all IDCS resources. Additionally, all internal resources of IDCS used for administration and configuration of IDCS itself are exposed as SCIM-based REST APIs. Access to the identity store 618 is isolated to the SCIM++ API.

In one embodiment, for example, the SCIM standard is implemented to manage the users and groups resources as defined by the SCIM specifications, while SCIM++ is configured to support additional IDCS internal resources (e.g., password policies, roles, settings, etc.) using the language defined by the SCIM standard.

The Administration service supports the SCIM 2.0 standard endpoints with the standard SCIM 2.0 core schemas and schema extensions where needed. In addition, the Administration service supports several SCIM 2.0 compliant endpoint extensions to manage other IDCS resources, for example, Users, Groups, Applications, Settings, etc. The Administration service also supports a set of remote procedure call-style (“RPC-style”) REST interfaces that do not perform CRUDQ operations but instead provide a functional service, for example, “UserPasswordGenerator,” “UserPasswordValidator,” etc.

IDCS Administration APIs use the OAuth2 protocol for authentication and authorization. IDCS supports common OAuth2 scenarios such as scenarios for web server, mobile, and JavaScript applications. Access to IDCS APIs is protected by access tokens. To access IDCS Administration APIs, an application needs to be registered as an OAuth2 client or an IDCS Application (in which case the OAuth2 client is created automatically) through the IDCS Administration console and be granted desired IDCS Administration Roles. When making IDCS Administration API calls, the application first requests an access token from the IDCS OAuth2 Service. After acquiring the token, the application sends the access token to the IDCS API by including it in the HTTP authorization header. Applications can use IDCS Administration REST APIs directly, or use an IDCS Java Client API Library.

Infrastructure Services

The IDCS infrastructure services support the functionality of IDCS platform services. These runtime services include an event processing service (for asynchronously processing user notifications, application subscriptions, and auditing to database); a job scheduler service (for scheduling and executing jobs, e.g., executing immediately or at a configured time long-running tasks that do not require user intervention); a cache management service; a storage management service (for integrating with a public cloud storage service); a reports service (for generating reports and dashboards); an SSO service (for managing internal user authentication and SSO); a user interface (“UI”) service (for hosting different types of UI clients); and a service manager service. Service manager is an internal interface between the Oracle Public Cloud and IDCS. Service manager manages commands issued by the Oracle Public Cloud, where the commands need to be implemented by IDCS. For example, when a customer signs up for an account in a cloud store before they can buy something, the cloud sends a request to IDCS asking to create a tenant. In this case, service manager implements the cloud specific operations that the cloud expects IDCS to support.

An IDCS microservice may call another IDCS microservice through a network interface (i.e., an HTTP request).

In one embodiment, IDCS may also provide a schema service (or a persistence service) that allows for using a database schema. A schema service allows for delegating the responsibility of managing database schemas to IDCS. Accordingly, a user of IDCS does not need to manage a database since there is an IDCS service that provides that functionality. For example, the user may use the database to persist schemas on a per tenant basis, and when there is no more space in the database, the schema service will manage the functionality of obtaining another database and growing the space so that the users do not have to manage the database themselves.

IDCS further includes data stores which are data repositories required/generated by IDCS, including an identity store 618 (storing users, groups, etc.), a global database 620 (storing configuration data used by IDCS to configure itself), an operational schema 622 (providing per tenant schema separation and storing customer data on a per customer basis), an audit schema 624 (storing audit data), a caching cluster 626 (storing cached objects to speed up performance), etc. All internal and external IDCS consumers integrate with the identity services over standards-based protocols. This enables use of a domain name system (“DNS”) to resolve where to route requests, and decouples consuming applications from understanding the internal implementation of identity services.

Real-Time and Near-Real-Time Tasks

IDCS separates the tasks of a requested service into synchronous real-time and asynchronous near-real-time tasks, where real-time tasks include only the operations that are needed for the user to proceed. In one embodiment, a real-time task is a task that is performed with minimal delay, and a near-real-time task is a task that is performed in the background without the user having to wait for it. In one embodiment, a real-time task is a task that is performed with substantially no delay or with negligible delay, and appears to a user as being performed almost instantaneously.

The real-time tasks perform the main business functionality of a specific identity service. For example, when requesting a login service, an application sends a message to authenticate a user's credentials and get a session cookie in return. What the user experiences is logging into the system. However, several other tasks may be performed in connection with the user's logging in, such as validating who the user is, auditing, sending notifications, etc. Accordingly, validating the credentials is a task that is performed in real-time so that the user is given an HTTP cookie to start a session, but the tasks related to notifications (e.g., sending an email to notify the creation of an account), audits (e.g., tracking/recording), etc., are near-real-time tasks that can be performed asynchronously so that the user can proceed with least delay.

When an HTTP request for a microservice is received, the corresponding real-time tasks are performed by the microservice in the middle tier, and the remaining near-real-time tasks such as operational logic/events that are not necessarily subject to real-time processing are offloaded to message queues 628 that support a highly scalable asynchronous event management system 630 with guaranteed delivery and processing. Accordingly, certain behaviors are pushed from the front end to the backend to enable IDCS to provide high level service to the customers by reducing latencies in response times. For example, a login process may include validation of credentials, submission of a log report, updating of the last login time, etc., but these tasks can be offloaded to a message queue and performed in near-real-time as opposed to real-time.

In one example, a system may need to register or create a new user. The system calls an IDCS SCIM API to create a user. The end result is that when the user is created in identity store 618, the user gets a notification email including a link to reset their password. When IDCS receives a request to register or create a new user, the corresponding microservice looks at configuration data in the operational database (located in global database 620 in FIG. 6) and determines that the “create user” operation is marked with a “create user” event which is identified in the configuration data as an asynchronous operation. The microservice returns to the client and indicates that the creation of the user is done successfully, but the actual sending of the notification email is postponed and pushed to the backend. In order to do so, the microservice uses a messaging API 616 to queue the message in queue 628 which is a store.

In order to dequeue queue 628, a messaging microservice, which is an infrastructure microservice, continually runs in the background and scans queue 628 looking for events in queue 628. The events in queue 628 are processed by event subscribers 630 such as audit, user notification, application subscriptions, data analytics, etc. Depending on the task indicated by an event, event subscribers 630 may communicate with, for example, audit schema 624, a user notification service 634, an identity event subscriber 632, etc. For example, when the messaging microservice finds the “create user” event in queue 628, it executes the corresponding notification logic and sends the corresponding email to the user.

In one embodiment, queue 628 queues operational events published by microservices 614 as well as resource events published by APIs 616 that manage IDCS resources.

IDCS uses a real-time caching structure to enhance system performance and user experience. The cache itself may also be provided as a microservice. IDCS implements an elastic cache cluster 626 that grows as the number of customers supported by IDCS scales. Cache cluster 626 may be implemented with a distributed data grid which is disclosed in more detail below. In one embodiment, write-only resources bypass cache.

In one embodiment, IDCS runtime components publish health and operational metrics to a public cloud monitoring module 636 that collects such metrics of a public cloud such as Oracle Public Cloud from Oracle Corp.

In one embodiment, IDCS may be used to create a user. For example, a client application 602 may issue a REST API call to create a user. Admin service (a platform service in 614) delegates the call to a user manager (an infrastructure library/service in 614), which in turn creates the user in the tenant-specific ID store stripe in ID store 618. On “User Create Success”, the user manager audits the operation to the audit table in audit schema 624, and publishes an “identity.user.create.success” event to message queue 628. Identity subscriber 632 picks up the event and sends a “Welcome” email to the newly created user, including newly created login details.

In one embodiment, IDCS may be used to grant a role to a user, resulting in a user provisioning action. For example, a client application 602 may issue a REST API call to grant a user a role. Admin service (a platform service in 614) delegates the call to a role manager (an infrastructure library/service in 614), who grants the user a role in the tenant-specific ID store stripe in ID store 618. On “Role Grant Success”, the role manager audits the operations to the audit table in audit schema 624, and publishes an “identity.user.role.grant.success” event to message queue 628. Identity subscriber 632 picks up the event and evaluates the provisioning grant policy. If there is an active application grant on the role being granted, a provisioning subscriber performs some validation, initiates account creation, calls out the target system, creates an account on the target system, and marks the account creation as successful. Each of these functionalities may result in publishing of corresponding events, such as “prov.account.create.initiate”, “prov.target.create.initiate”, “prov.target.create.success”, or “prov.account.create.success”. These events may have their own business metrics aggregating number of accounts created in the target system over the last N days.

In one embodiment, IDCS may be used for a user to log in. For example, a client application 602 may use one of the supported authentication flows to request a login for a user. IDCS authenticates the user, and upon success, audits the operation to the audit table in audit schema 624. Upon failure, IDCS audits the failure in audit schema 624, and publishes “login.user.login.failure” event in message queue 628. A login subscriber picks up the event, updates its metrics for the user, and determines if additional analytics on the user's access history need to be performed.

Accordingly, by implementing “inversion of control” functionality (e.g., changing the flow of execution to schedule the execution of an operation at a later time so that the operation is under the control of another system), embodiments enable additional event queues and subscribers to be added dynamically to test new features on a small user sample before deploying to broader user base, or to process specific events for specific internal or external customers.

Stateless Functionality

IDCS microservices are stateless, meaning the microservices themselves do not maintain state. “State” refers to the data that an application uses in order to perform its capabilities. IDCS provides multi-tenant functionality by persisting all state into tenant specific repositories in the IDCS data tier. The middle tier (i.e., the code that processes the requests) does not have data stored in the same location as the application code. Accordingly, IDCS is highly scalable, both horizontally and vertically.

To scale vertically (or scale up/down) means to add resources to (or remove resources from) a single node in a system, typically involving the addition of CPUs or memory to a single computer. Vertical scalability allows an application to scale up to the limits of its hardware. To scale horizontally (or scale out/in) means to add more nodes to (or remove nodes from) a system, such as adding a new computer to a distributed software application. Horizontal scalability allows an application to scale almost infinitely, bound only by the amount of bandwidth provided by the network.

Stateless-ness of the middle tier of IDCS makes it horizontally scalable just by adding more CPUs, and the IDCS components that perform the work of the application do not need to have a designated physical infrastructure where a particular application is running. Stateless-ness of the IDCS middle tier makes IDCS highly available, even when providing identity services to a very large number of customers/tenants. Each pass through an IDCS application/service is focused on CPU usage only to perform the application transaction itself but not use hardware to store data. Scaling is accomplished by adding more slices when the application is running, while data for the transaction is stored at a persistence layer where more copies can be added when needed.

The IDCS web tier, middle tier, and data tier can each scale independently and separately. The web tier can be scaled to handle more HTTP requests. The middle tier can be scaled to support more service functionality. The data tier can be scaled to support more tenants.

IDCS Functional View

FIG. 6A is an example block diagram 600 b of a functional view of IDCS in one embodiment. In block diagram 600 b, the IDCS functional stack includes services, shared libraries, and data stores. The services include IDCS platform services 640 b, IDCS premium services 650 b, and IDCS infrastructure services 662 b. In one embodiment, IDCS platform services 640 b and IDCS premium services 650 b are separately deployed Java-based runtime services implementing the business of IDCS, and IDCS infrastructure services 662 b are separately deployed runtime services providing infrastructure support for IDCS. The shared libraries include IDCS infrastructure libraries 680 b which are common code packaged as shared libraries used by IDCS services and shared libraries. The data stores are data repositories required/generated by IDCS, including identity store 698 b, global configuration 700 b, message store 702 b, global tenant 704 b, personalization settings 706 b, resources 708 b, user transient data 710 b, system transient data 712 b, per-tenant schemas (managed ExaData) 714 b, operational store (not shown), caching store (not shown), etc.

In one embodiment, IDCS platform services 640 b include, for example, OpenID Connect service 642 b, OAuth2 service 644 b, SAML2 service 646 b, and SCIM++ service 648 b. In one embodiment, IDCS premium services include, for example, cloud SSO and governance 652 b, enterprise governance 654 b, AuthN broker 656 b, federation broker 658 b, and private account management 660 b.

IDCS infrastructure services 662 b and IDCS infrastructure libraries 680 b provide supporting capabilities as required by IDCS platform services 640 b to do their work. In one embodiment, IDCS infrastructure services 662 b include job scheduler 664 b, UI 666 b, SSO 668 b, reports 670 b, cache 672 b, storage 674 b, service manager 676 b (public cloud control), and event processor 678 b (user notifications, app subscriptions, auditing, data analytics). In one embodiment, IDCS infrastructure libraries 680 b include data manager APIs 682 b, event APIs 684 b, storage APIs 686 b, authentication APIs 688 b, authorization APIs 690 b, cookie APIs 692 b, keys APIs 694 b, and credentials APIs 696 b. In one embodiment, cloud compute service 602 b (internal Nimbula) supports the function of IDCS infrastructure services 662 b and IDCS infrastructure libraries 680 b.

In one embodiment, IDCS provides various UIs 602 b for a consumer of IDCS services, such as customer end user UI 604 b, customer admin UI 606 b, DevOps admin UI 608 b, and login UI 610 b. In one embodiment, IDCS allows for integration 612 b of applications (e.g., customer apps 614 b, partner apps 616 b, and cloud apps 618 b) and firmware integration 620 b. In one embodiment, various environments may integrate with IDCS to support their access control needs. Such integration may be provided by, for example, identity bridge 622 b (providing AD integration, WNA, and SCIM connector), Apache agent 624 b, or MSFT agent 626 b.

In one embodiment, internal and external IDCS consumers integrate with the identity services of IDCS over standards-based protocols 628 b, such as Open ID Connect 630 b, OAuth2 632 b, SAML2 634 b, SCIM 636 b, and REST/HTTP 638 b. This enables use of a domain name system (“DNS”) to resolve where to route requests, and decouples the consuming applications from understanding internal implementation of the identity services.

The IDCS functional view in FIG. 6A further includes public cloud infrastructure services that provide common functionality that IDCS depends on for user notifications (cloud notification service 718 b), file storage (cloud storage service 716 b), and metrics/alerting for DevOps (cloud monitoring service (EM) 722 b and cloud metrics service (Graphite) 720 b).

Cloud Gate

In one embodiment, IDCS implements a “Cloud Gate” in the web tier. Cloud Gate is a web server plugin that enables web applications to externalize user SSO to an identity management system (e.g., IDCS), similar to WebGate or WebAgent technologies that work with enterprise IDM stacks. Cloud Gate acts as a security gatekeeper that secures access to IDCS APIs. In one embodiment, Cloud Gate is implemented by a web/proxy server plugin that provides a web Policy Enforcement Point (“PEP”) for protecting HTTP resources based on OAuth.

FIG. 7 is a block diagram 700 of an embodiment that implements a Cloud Gate 702 running in a web server 712 and acting as a Policy Enforcement Point (“PEP”) configured to integrate with IDCS Policy Decision Point (“PDP”) using open standards (e.g., OAuth2, Open ID Connect, etc.) while securing access to web browser and REST API resources 714 of an application. In some embodiments, the PDP is implemented at OAuth and/or Open ID Connect microservices 704. For example, when a user browser 706 sends a request to IDCS for a login of a user 710, a corresponding IDCS PDP validates the credentials and then decides whether the credentials are sufficient (e.g., whether to request for further credentials such as a second password). In the embodiment of FIG. 7, Cloud Gate 702 may act both as the PEP and as the PDP since it has a local policy.

As part of one-time deployment, Cloud Gate 702 is registered with IDCS as an OAuth2 client, enabling it to request OIDC and OAuth2 operations against IDCS. Thereafter, it maintains configuration information about an application's protected and unprotected resources, subject to request matching rules (how to match URLs, e.g., with wild cards, regular expressions, etc.). Cloud Gate 702 can be deployed to protect different applications having different security policies, and the protected applications can be multi-tenant.

During web browser-based user access, Cloud Gate 702 acts as an OIDC RP 718 initiating a user authentication flow. If user 710 has no valid local user session, Cloud Gate 702 re-directs the user to the SSO microservice and participates in the OIDC “Authorization Code” flow with the SSO microservice. The flow concludes with the delivery of a JWT as an identity token. Cloud Gate 708 validates the JWT (e.g., looks at signature, expiration, destination/audience, etc.) and issues a local session cookie for user 710. It acts as a session manager 716 securing web browser access to protected resources and issuing, updating, and validating the local session cookie. It also provides a logout URL for removal of its local session cookie.

Cloud Gate 702 also acts as an HTTP Basic Auth authenticator, validating HTTP Basic Auth credentials against IDCS. This behavior is supported in both session-less and session-based (local session cookie) modes. No server-side IDCS session is created in this case.

During programmatic access by REST API clients 708, Cloud Gate 702 may act as an OAuth2 resource server/filter 720 for an application's protected REST APIs 714. It checks for the presence of a request with an authorization header and an access token. When client 708 (e.g., mobile, web apps, JavaScript, etc.) presents an access token (issued by IDCS) to use with a protected REST API 714, Cloud Gate 702 validates the access token before allowing access to the API (e.g., signature, expiration, audience, etc.). The original access token is passed along unmodified.

Generally, OAuth is used to generate either a client identity propagation token (e.g., indicating who the client is) or a user identity propagation token (e.g., indicating who the user is). In the embodiments, the implementation of OAuth in Cloud Gate is based on a JWT which defines a format for web tokens, as provided by, e.g., IETF, RFC 7519.

When a user logs in, a JWT is issued. The JWT is signed by IDCS and supports multi-tenant functionality in IDCS. Cloud Gate validates the JWT issued by IDCS to allow for multi-tenant functionality in IDCS. Accordingly, IDCS provides multi-tenancy in the physical structure as well as in the logical business process that underpins the security model.

Tenancy Types

IDCS specifies three types of tenancies: customer tenancy, client tenancy, and user tenancy. Customer or resource tenancy specifies who the customer of IDCS is (i.e., for whom is the work being performed). Client tenancy specifies which client application is trying to access data (i.e., what application is doing the work). User tenancy specifies which user is using the application to access data (i.e., by whom is the work being performed). For example, when a professional services company provides system integration functionality for a warehouse club and uses IDCS for providing identity management for the warehouse club systems, user tenancy corresponds to the professional services company, client tenancy is the application that is used to provide system integration functionality, and customer tenancy is the warehouse club.

Separation and identification of these three tenancies enables multi-tenant functionality in a cloud-based service. Generally, for on-premise software that is installed on a physical machine on-premise, there is no need to specify three different tenancies since a user needs to be physically on the machine to log in. However, in a cloud-based service structure, embodiments use tokens to determine who is using what application to access which resources. The three tenancies are codified by tokens, enforced by Cloud Gate, and used by the business services in the middle tier. In one embodiment, an OAuth server generates the tokens. In various embodiments, the tokens may be used in conjunction with any security protocol other than OAuth.

Decoupling user, client, and resource tenancies provides substantial business advantages for the users of the services provided by IDCS. For example, it allows a service provider that understands the needs of a business (e.g., a healthcare business) and their identity management problems to buy services provided by IDCS, develop their own backend application that consumes the services of IDCS, and provide the backend applications to the target businesses. Accordingly, the service provider may extend the services of IDCS to provide their desired capabilities and offer those to certain target businesses. The service provider does not have to build and run software to provide identity services but can instead extend and customize the services of IDCS to suit the needs of the target businesses.

Some known systems only account for a single tenancy which is customer tenancy. However, such systems are inadequate when dealing with access by a combination of users such as customer users, customer's partners, customer's clients, clients themselves, or clients that customer has delegated access to. Defining and enforcing multiple tenancies in the embodiments facilitates the identity management functionality over such variety of users.

In one embodiment, one entity of IDCS does not belong to multiple tenants at the same time; it belongs to only one tenant, and a “tenancy” is where artifacts live. Generally, there are multiple components that implement certain functions, and these components can belong to tenants or they can belong to infrastructure. When infrastructure needs to act on behalf of tenants, it interacts with an entity service on behalf of the tenant. In that case, infrastructure itself has its own tenancy and customer has its own tenancy. When a request is submitted, there can be multiple tenancies involved in the request.

For example, a client that belongs to “tenant 1” may execute a request to get a token for “tenant 2” specifying a user in “tenant 3.” As another example, a user living in “tenant 1” may need to perform an action in an application owned by “tenant 2”. Thus, the user needs to go to the resource namespace of “tenant 2” and request a token for themselves. Accordingly, delegation of authority is accomplished by identifying “who” can do “what” to “whom.” As yet another example, a first user working for a first organization (“tenant 1”) may allow a second user working for a second organization (“tenant 2”) to have access to a document hosted by a third organization (“tenant 3”).

In one example, a client in “tenant 1” may request an access token for a user in “tenant 2” to access an application in “tenant 3”. The client may do so by invoking an OAuth request for the token by going to “http://tenant3/oauth/token”. The client identifies itself as a client that lives in “tenant 1” by including a “client assertion” in the request. The client assertion includes a client ID (e.g., “client 1”) and the client tenancy “tenant 1”. As “client 1” in “tenant 1”, the client has the right to invoke a request for a token on “tenant 3”, and the client wants the token for a user in “tenant 2”. Accordingly, a “user assertion” is also passed as part of the same HTTP request. The access token that is generated will be issued in the context of the target tenancy which is the application tenancy (“tenant 3”) and will include the user tenancy (“tenant 2”).

In one embodiment, in the data tier, each tenant is implemented as a separate stripe. From a data management perspective, artifacts live in a tenant. From a service perspective, a service knows how to work with different tenants, and the multiple tenancies are different dimensions in the business function of a service. FIG. 8 illustrates an example system 800 implementing multiple tenancies in an embodiment. System 800 includes a client 802 that requests a service provided by a microservice 804 that understands how to work with data in a database 806. The database includes multiple tenants 808 and each tenant includes the artifacts of the corresponding tenancy. In one embodiment, microservice 804 is an OAuth microservice requested through https://tenant3/oauth/token for getting a token. The function of the OAuth microservice is performed in microservice 804 using data from database 806 to verify that the request of client 802 is legitimate, and if it is legitimate, use the data from different tenancies 808 to construct the token. Accordingly, system 800 is multi-tenant in that it can work in a cross-tenant environment by not only supporting services coming into each tenancy, but also supporting services that can act on behalf of different tenants.

System 800 is advantageous since microservice 804 is physically decoupled from the data in database 806, and by replicating the data across locations that are closer to the client, microservice 804 can be provided as a local service to the clients and system 800 can manage the availability of the service and provide it globally.

In one embodiment, microservice 804 is stateless, meaning that the machine that runs microservice 804 does not maintain any markers pointing the service to any specific tenants. Instead, a tenancy may be marked, for example, on the host portion of a URL of a request that comes in. That tenancy points to one of tenants 808 in database 806. When supporting a large number of tenants (e.g., millions of tenants), microservice 804 cannot have the same number of connections to database 806, but instead uses a connection pool 810 which provides the actual physical connections to database 806 in the context of a database user.

Generally, connections are built by supplying an underlying driver or provider with a connection string, which is used to address a specific database or server and to provide instance and user authentication credentials (e.g., “Server=sql_box;Database=Common;User ID=uid;Pwd=password;”). Once a connection has been built, it can be opened and closed, and properties (e.g., the command time-out length, or transaction, if one exists) can be set. The connection string includes a set of key-value pairs, dictated by the data access interface of the data provider. A connection pool is a cache of database connections maintained so that the connections can be reused when future requests to a database are required. In connection pooling, after a connection is created, it is placed in the pool and it is used again so that a new connection does not have to be established. For example, when there needs to be ten connections between microservice 804 and database 808, there will be ten open connections in connection pool 810, all in the context of a database user (e.g., in association with a specific database user, e.g., who is the owner of that connection, whose credentials are being validated, is it a database user, is it a system credential, etc.).

The connections in connection pool 810 are created for a system user that can access anything. Therefore, in order to correctly handle auditing and privileges by microservice 804 processing requests on behalf of a tenant, the database operation is performed in the context of a “proxy user” 812 associated with the schema owner assigned to the specific tenant. This schema owner can access only the tenancy that the schema was created for, and the value of the tenancy is the value of the schema owner. When a request is made for data in database 806, microservice 804 uses the connections in connection pool 810 to provide that data. Accordingly, multi-tenancy is achieved by having stateless, elastic middle tier services process incoming requests in the context of (e.g., in association with) the tenant-specific data store binding established on a per request basis on top of the data connection created in the context of (e.g., in association with) the data store proxy user associated with the resource tenancy, and the database can scale independently of the services.

The following provides an example functionality for implementing proxy user 812:

dbOperation=<prepare DB command to execute>

dbConnection=getDBConnectionFromPool( )

dbConnection.setProxyUser (resourceTenant)

result=dbConnection.executeOperation (dbOperation)

In this functionality, microservice 804 sets the “Proxy User” setting on the connection pulled from connection pool 810 to the “Tenant,” and performs the database operation in the context of the tenant while using the database connection in connection pool 810.

When striping every table to configure different columns in a same database for different tenants, one table may include all tenants' data mixed together. In contrast, one embodiment provides a tenant-driven data tier. The embodiment does not stripe the same database for different tenants, but instead provides a different physical database per tenant. For example, multi-tenancy may be implemented by using a pluggable database (e.g., Oracle Database 12 c from Oracle Corp.) where each tenant is allocated a separate partition. At the data tier, a resource manager processes the request and then asks for the data source for the request (separate from metadata). The embodiment performs runtime switch to a respective data source/store per request. By isolating each tenant's data from the other tenants, the embodiment provides improved data security.

In one embodiment, various tokens codify different tenancies. A URL token may identify the tenancy of the application that requests a service. An identity token may codify the identity of a user that is to be authenticated. An access token may identify multiple tenancies. For example, an access token may codify the tenancy that is the target of such access (e.g., an application tenancy) as well as the user tenancy of the user that is given access. A client assertion token may identify a client ID and the client tenancy. A user-assertion token may identify the user and the user tenancy.

In one embodiment, an identity token includes at least a claim indicating the user tenant name (i.e., where the user lives).

In one embodiment, an access token includes at least a claim indicating the resource tenant name at the time the request for the access token was made (e.g., the customer), a claim indicating the user tenant name, a claim indicating the name of the OAuth client making the request, and a claim indicating the client tenant name. In one embodiment, an access token may be implemented according to the following JSON functionality:

{ ... ″ tok_type ″ : ″AT″, ″user_id″ : ″testuser″, ″user_tenantname″ : ″<value-of-identity-tenant>″ “tenant” : “<value-of-resource-tenant>” “client_id” : “testclient”, “client_tenantname”: “<value-of-client-tenant>” ... }

In one embodiment, a client assertion token includes at least a claim indicating the client tenant name, and a claim indicating the name of the OAuth client making the request.

The tokens and/or multiple tenancies described herein may be implemented in any multi-tenant cloud-based service other than IDCS. For example, the tokens and/or multiple tenancies described herein may be implemented in SaaS or Enterprise Resource Planning (“ERP”) services.

FIG. 9 is a block diagram of a network view 900 of IDCS in one embodiment. FIG. 9 illustrates network interactions that are performed in one embodiment between application “zones” 904. Applications are broken into zones based on the required level of protection and the implementation of connections to various other systems (e.g., SSL zone, no SSL zone, etc.). Some application zones provide services that require access from the inside of IDCS, while some application zones provide services that require access from the outside of IDCS, and some are open access. Accordingly, a respective level of protection is enforced for each zone.

In the embodiment of FIG. 9, service to service communication is performed using HTTP requests. In one embodiment, IDCS uses the access tokens described herein not only to provide services but also to secure access to and within IDCS itself. In one embodiment, IDCS microservices are exposed through RESTful interfaces and secured by the tokens described herein.

In the embodiment of FIG. 9, any one of a variety of applications/services 902 may make HTTP calls to IDCS APIs to use IDCS services. In one embodiment, the HTTP requests of applications/services 902 go through an Oracle Public Cloud Load Balancing External Virtual IP address (“VIP”) 906 (or other similar technologies), a public cloud web routing tier 908, and an IDCS Load Balancing Internal VIP appliance 910 (or other similar technologies), to be received by IDCS web routing tier 912. IDCS web routing tier 912 receives the requests coming in from the outside or from the inside of IDCS and routes them across either an IDCS platform services tier 914 or an IDCS infrastructure services tier 916. IDCS platform services tier 914 includes IDCS microservices that are invoked from the outside of IDCS, such as Open ID Connect, OAuth, SAML, SCIM, etc. IDCS infrastructure services tier 916 includes supporting microservices that are invoked from the inside of IDCS to support the functionality of other IDCS microservices. Examples of IDCS infrastructure microservices are UI, SSO, reports, cache, job scheduler, service manager, functionality for making keys, etc. An IDCS cache tier 926 supports caching functionality for IDCS platform services tier 914 and IDCS infrastructure services tier 916.

By enforcing security both for outside access to IDCS and within IDCS, customers of IDCS can be provided with outstanding security compliance for the applications they run.

In the embodiment of FIG. 9, other than the data tier 918 which communicates based on Structured Query Language (“SQL”) and the ID store tier 920 that communicates based on LDAP, OAuth protocol is used to protect the communication among IDCS components (e.g., microservices) within IDCS, and the same tokens that are used for securing access from the outside of IDCS are also used for security within IDCS. That is, web routing tier 912 uses the same tokens and protocols for processing the requests it receives regardless of whether a request is received from the outside of IDCS or from the inside of IDCS. Accordingly, IDCS provides a single consistent security model for protecting the entire system, thereby allowing for outstanding security compliance since the fewer security models implemented in a system, the more secure the system is.

In the IDCS cloud environment, applications communicate by making network calls. The network call may be based on an applicable network protocol such as HTTP, Transmission Control Protocol (“TCP”), User Datagram Protocol (“UDP”), etc. For example, an application “X” may communicate with an application “Y” based on HTTP by exposing application “Y” as an HTTP Uniform Resource Locator (“URL”). In one embodiment, “Y” is an IDCS microservice that exposes a number of resources each corresponding to a capability. When “X” (e.g., another IDCS microservice) needs to call “Y”, it constructs a URL that includes “Y” and the resource/capability that needs to be invoked (e.g., https:/host/Y/resource), and makes a corresponding REST call which goes through web routing tier 912 and gets directed to “Y”.

In one embodiment, a caller outside the IDCS may not need to know where “Y” is, but web routing tier 912 needs to know where application “Y” is running. In one embodiment, IDCS implements discovery functionality (implemented by an API of OAuth service) to determine where each application is running so that there is no need for the availability of static routing information.

In one embodiment, an enterprise manager (“EM”) 922 provides a “single pane of glass” that extends on-premise and cloud-based management to IDCS. In one embodiment, a “Chef” server 924 which is a configuration management tool from Chef Software, Inc., provides configuration management functionality for various IDCS tiers. In one embodiment, a service deployment infrastructure and/or a persistent stored module 928 may send OAuth2 HTTP messages to IDCS web routing tier 912 for tenant lifecycle management operations, public cloud lifecycle management operations, or other operations. In one embodiment, IDCS infrastructure services tier 916 may send ID/password HTTP messages to a public cloud notification service 930 or a public cloud storage service 932.

Cloud Access Control-SSO

One embodiment supports lightweight cloud standards for implementing a cloud scale SSO service. Examples of lightweight cloud standards are HTTP, REST, and any standard that provides access through a browser (since a web browser is lightweight). On the contrary, SOAP is an example of a heavy cloud standard which requires more management, configuration, and tooling to build a client with. The embodiment uses Open ID Connect semantics for applications to request user authentication against IDCS. The embodiment uses lightweight HTTP cookie-based user session tracking to track user's active sessions at IDCS without statefull server-side session support. The embodiment uses JWT-based identity tokens for applications to use in mapping an authenticated identity back to their own local session. The embodiment supports integration with federated identity management systems, and exposes SAML IDP support for enterprise deployments to request user authentication against IDCS.

FIG. 10 is a block diagram 1000 of a system architecture view of SSO functionality in IDCS in one embodiment. The embodiment enables client applications to leverage standards-based web protocols to initiate user authentication flows. Applications requiring SSO integration with a cloud system may be located in enterprise data centers, in remote partner data centers, or even operated by a customer on-premise. In one embodiment, different IDCS platform services implement the business of SSO, such as Open ID Connect for processing login/logout requests from connected native applications (i.e., applications utilizing OpenID Connect to integrate with IDCS); SAML IDP service for processing browser-based login/logout requests from connected applications; SAML SP service for orchestrating user authentication against an external SAML IDP; and an internal IDCS SSO service for orchestrating end user login ceremony including local or federated login flows, and for managing IDCS host session cookie. Generally, HTTP works either with a form or without a form. When it works with a form, the form is seen within a browser. When it works without a form, it functions as a client to server communication. Both Open ID Connect and SAML require the ability to render a form, which may be accomplished by presence of a browser or virtually performed by an application that acts as if there is a browser. In one embodiment, an application client implementing user authentication/SSO through IDCS needs to be registered in IDCS as an OAuth2 client and needs to obtain client identifier and credentials (e.g., ID/password, ID/certificate, etc.).

The example embodiment of FIG. 10 includes three components/microservices that collectively provide login capabilities, including two platform microservices: OAuth2 1004 and SAML2 1006, and one infrastructure microservice: SSO 1008. In the embodiment of FIG. 10, IDCS provides an “Identity Metasystem” in which SSO services 1008 are provided over different types of applications, such as browser based web or native applications 1010 requiring 3-legged OAuth flow and acting as an Open ID Connect relaying party (“RP,” an application that outsources its user authentication function to an IDP), native applications 1011 requiring 2-legged OAuth flow and acting as an OpenID Connect RP, and web applications 1012 acting as a SAML SP.

Generally, an Identity Metasystem is an interoperable architecture for digital identity, allowing for employing a collection of digital identities based on multiple underlying technologies, implementations, and providers. LDAP, SAML, and OAuth are examples of different security standards that provide identity capability and can be the basis for building applications, and an Identity Metasystem may be configured to provide a unified security system over such applications. The LDAP security model specifies a specific mechanism for handling identity, and all passes through the system are to be strictly protected. SAML was developed to allow one set of applications securely exchange information with another set of applications that belong to a different organization in a different security domain. Since there is no trust between the two applications, SAML was developed to allow for one application to authenticate another application that does not belong to the same organization. OAuth provides Open ID Connect that is a lightweight protocol for performing web based authentication.

In the embodiment of FIG. 10, when an OpenID application 1010 connects to an Open ID server in IDCS, its “channels” request SSO service. Similarly, when a SAML application 1012 connects to a SAML server in IDCS, its “channels” also request SSO service. In IDCS, a respective microservice (e.g., an Open ID microservice 1004 and a SAML microservice 1006) will handle each of the applications, and these microservices request SSO capability from SSO microservice 1008. This architecture can be expanded to support any number of other security protocols by adding a microservice for each protocol and then using SSO microservice 1008 for SSO capability. SSO microservice 1008 issues the sessions (i.e., an SSO cookie 1014 is provided) and is the only system in the architecture that has the authority to issue a session. An IDCS session is realized through the use of SSO cookie 1014 by browser 1002. Browser 1002 also uses a local session cookie 1016 to manage its local session.

In one embodiment, for example, within a browser, a user may use a first application based on SAML and get logged in, and later use a second application built with a different protocol such as OAuth. The user is provided with SSO on the second application within the same browser. Accordingly, the browser is the state or user agent and maintains the cookies.

In one embodiment, SSO microservice 1008 provides login ceremony 1018, ID/password recovery 1020, first time login flow 1022, an authentication manager 1024, an HTTP cookie manager 1026, and an event manager 1028. Login ceremony 1018 implements SSO functionality based on customer settings and/or application context, and may be configured according to a local form (i.e., basic Auth), an external SAML IDP, an external OIDC IDP, etc. ID/password recovery 1020 is used to recover a user's ID and/or password. First time login flow 1022 is implemented when a user logs in for the first time (i.e., an SSO session does not yet exist). Authentication manager 1024 issues authentication tokens upon successful authentication. HTTP cookie manager 1026 saves the authentication token in an SSO cookie. Event manager 1028 publishes events related to SSO functionality.

In one embodiment, interactions between OAuth microservice 1004 and SSO microservice 1008 are based on browser redirects so that SSO microservice 1008 challenges the user using an HTML form, validates credentials, and issues a session cookie.

In one embodiment, for example, OAuth microservice 1004 may receive an authorization request from browser 1002 to authenticate a user of an application according to 3-legged OAuth flow. OAuth microservice 1004 then acts as an OIDC provider 1030, redirects browser 1002 to SSO microservice 1008, and passes along application context. Depending on whether the user has a valid SSO session or not, SSO microservice 1008 either validates the existing session or performs a login ceremony. Upon successful authentication or validation, SSO microservice 1008 returns authentication context to OAuth microservice 1004. OAuth microservice 1004 then redirects browser 1002 to a callback URL with an authorization (“AZ”) code. Browser 1002 sends the AZ code to OAuth microservice 1004 to request the required tokens 1032. Browser 1002 also includes its client credentials (obtained when registering in IDCS as an OAuth2 client) in the HTTP authorization header. OAuth microservice 1004 in return provides the required tokens 1032 to browser 1002. In one embodiment, tokens 1032 provided to browser 1002 include JW identity and access tokens signed by the IDCS OAuth2 server. Further details of this functionality are disclosed below with reference to FIG. 11.

In one embodiment, for example, OAuth microservice 1004 may receive an authorization request from a native application 1011 to authenticate a user according to a 2-legged OAuth flow. In this case, an authentication manager 1034 in OAuth microservice 1004 performs the corresponding authentication (e.g., based on ID/password received from a client 1011) and a token manager 1036 issues a corresponding access token upon successful authentication.

In one embodiment, for example, SAML microservice 1006 may receive an SSO POST request from a browser to authenticate a user of a web application 1012 that acts as a SAML SP. SAML microservice 1006 then acts as a SAML IDP 1038, redirects browser 1002 to SSO microservice 1008, and passes along application context. Depending on whether the user has a valid SSO session or not, SSO microservice 1008 either validates the existing session or performs a login ceremony. Upon successful authentication or validation, SSO microservice 1008 returns authentication context to SAML microservice 1006. SAML microservice then redirects to the SP with required tokens.

In one embodiment, for example, SAML microservice 1006 may act as a SAML SP 1040 and go to a remote SAML IDP 1042 (e.g., an active directory federation service (“ADFS”)). One embodiment implements the standard SAML/AD flows. In one embodiment, interactions between SAML microservice 1006 and SSO microservice 1008 are based on browser redirects so that SSO microservice 1008 challenges the user using an HTML form, validates credentials, and issues a session cookie.

In one embodiment, the interactions between a component within IDCS (e.g., 1004, 1006, 1008) and a component outside IDCS (e.g., 1002, 1011, 1042) are performed through firewalls 1044.

Login/Logout Flow

FIG. 11 is a message sequence flow 1100 of SSO functionality provided by IDCS in one embodiment. When a user uses a browser 1102 to access a client 1106 (e.g., a browser-based application or a mobile/native application), Cloud Gate 1104 acts as an application enforcement point and enforces a policy defined in a local policy text file. If Cloud Gate 1104 detects that the user has no local application session, it requires the user to be authenticated. In order to do so, Cloud Gate 1104 redirects browser 1102 to OAuth2 microservice 1110 to initiate OpenID Connect login flow against the OAuth2 microservice 1110 (3-legged AZ Grant flow with scopes=“openid profile”).

The request of browser 1102 traverses IDCS routing tier web service 1108 and Cloud Gate 1104 and reaches OAuth2 microservice 1110. OAuth2 microservice 1110 constructs the application context (i.e., metadata that describes the application, e.g., identity of the connecting application, client ID, configuration, what the application can do, etc.), and redirects browser 1102 to SSO microservice 1112 to log in.

If the user has a valid SSO session, SSO microservice 1112 validates the existing session without starting a login ceremony. If the user does not have a valid SSO session (i.e., no session cookie exists), the SSO microservice 1112 initiates the user login ceremony in accordance with customer's login preferences (e.g., displaying a branded login page). In order to do so, the SSO microservice 1112 redirects browser 1102 to a login application service 1114 implemented in JavaScript. Login application service 1114 provides a login page in browser 1102. Browser 1102 sends a REST POST to the SSO microservice 1112 including login credentials. The SSO microservice 1112 generates an access token and sends it to Cloud Gate 1104 in a REST POST. Cloud Gate 1104 sends the authentication information to Admin SCIM microservice 1116 to validate the user's password. Admin SCIM microservice 1116 determines successful authentication and sends a corresponding message to SSO microservice 1112.

In one embodiment, during the login ceremony, the login page does not display a consent page, as “login” operation requires no further consent. Instead, a privacy policy is stated on the login page, informing the user about certain profile attributes being exposed to applications. During the login ceremony, the SSO microservice 1112 respects customer's IDP preferences, and if configured, redirects to the IDP for authentication against the configured IDP.

Upon successful authentication or validation, SSO microservice 1112 redirects browser 1102 back to OAuth2 microservice 1110 with the newly created/updated SSO host HTTP cookie (e.g., the cookie that is created in the context of the host indicated by “HOSTURL”) containing the user's authentication token. OAuth2 microservice 1110 returns AZ Code (e.g., an OAuth concept) back to browser 1102 and redirects to Cloud Gate 1104. Browser 1102 sends AZ Code to Cloud Gate 1104, and Cloud Gate 1104 sends a REST POST to OAuth2 microservice 1110 to request the access token and the identity token. Both tokens are scoped to OAuth microservice 1110 (indicated by the audience token claim). Cloud Gate 1104 receives the tokens from OAuth2 microservice 1110.

Cloud Gate 1104 uses the identity token to map the user's authenticated identity to its internal account representation, and it may save this mapping in its own HTTP cookie. Cloud Gate 1104 then redirects browser 1102 to client 1106. Browser 1102 then reaches client 1106 and receives a corresponding response from client 1106. From this point on, browser 1102 can access the application (i.e., client 1106) seamlessly for as long as the application's local cookie is valid. Once the local cookie becomes invalid, the authentication process is repeated.

Cloud Gate 1104 further uses the access token received in a request to obtain “userinfo” from OAuth2 microservice 1110 or the SCIM microservice. The access token is sufficient to access the “userinfo” resource for the attributes allowed by the “profile” scope. It is also sufficient to access “/me” resources via the SCIM microservice. In one embodiment, by default, the received access token is only good for user profile attributes that are allowed under the “profile” scope. Access to other profile attributes is authorized based on additional (optional) scopes submitted in the AZ grant login request issued by Cloud Gate 1104.

When the user accesses another OAuth2 integrated connecting application, the same process repeats.

In one embodiment, the SSO integration architecture uses a similar OpenID Connect user authentication flow for browser-based user logouts. In one embodiment, a user with an existing application session accesses Cloud Gate 1104 to initiate a logout. Alternatively, the user may have initiated the logout on the IDCS side. Cloud Gate 1104 terminates the application-specific user session, and initiates OAuth2 OpenID Provider (“OP”) logout request against OAuth2 microservice 1110. OAuth2 microservice 1110 redirects to SSO microservice 1112 that kills the user's host SSO cookie. SSO microservice 1112 initiates a set of redirects (OAuth2 OP and SAML IDP) against known logout endpoints as tracked in user's SSO cookie.

In one embodiment, if Cloud Gate 1104 uses SAML protocol to request user authentication (e.g., login), a similar process starts between the SAML microservice and SSO microservice 1112.

Cloud Cache

One embodiment provides a service/capability referred to as Cloud Cache. Cloud Cache is provided in IDCS to support communication with applications that are LDAP based (e.g., email servers, calendar servers, some business applications, etc.) since IDCS does not communicate according to LDAP while such applications are configured to communicate only based on LDAP. Typically, cloud directories are exposed via REST APIs and do not communicate according to the LDAP protocol. Generally, managing LDAP connections across corporate firewalls requires special configurations that are difficult to set up and manage.

To support LDAP based applications, Cloud Cache translates LDAP communications to a protocol suitable for communication with a cloud system. Generally, an LDAP based application uses a database via LDAP. An application may be alternatively configured to use a database via a different protocol such as SQL. However, LDAP provides a hierarchical representation of resources in tree structures, while SQL represents data as tables and fields. Accordingly, LDAP may be more desirable for searching functionality, while SQL may be more desirable for transactional functionality.

In one embodiment, services provided by IDCS may be used in an LDAP based application to, for example, authenticate a user of the applications (i.e., an identity service) or enforce a security policy for the application (i.e., a security service). In one embodiment, the interface with IDCS is through a firewall and based on HTTP (e.g., REST). Typically, corporate firewalls do not allow access to internal LDAP communication even if the communication implements Secure Sockets Layer (“SSL”), and do not allow a TCP port to be exposed through the firewall. However, Cloud Cache translates between LDAP and HTTP to allow LDAP based applications reach services provided by IDCS, and the firewall will be open for HTTP.

Generally, an LDAP directory may be used in a line of business such as marketing and development, and defines users, groups, works, etc. In one example, a marketing and development business may have different targeted customers, and for each customer, may have their own applications, users, groups, works, etc. Another example of a line of business that may run an LDAP cache directory is a wireless service provider. In this case, each call made by a user of the wireless service provider authenticates the user's device against the LDAP directory, and some of the corresponding information in the LDAP directory may be synchronized with a billing system. In these examples, LDAP provides functionality to physically segregate content that is being searched at runtime.

In one example, a wireless service provider may handle its own identity management services for their core business (e.g., regular calls), while using services provided by IDCS in support of a short term marketing campaign. In this case, Cloud Cache “flattens” LDAP when it has a single set of users and a single set of groups that it runs against the cloud. In one embodiment, any number of Cloud Caches may be implemented in IDCS.

Distributed Data Grid

In one embodiment, the cache cluster in IDCS is implemented based on a distributed data grid, as disclosed, for example, in U.S. Pat. Pub. No. 2016/0092540, the disclosure of which is hereby incorporated by reference. A distributed data grid is a system in which a collection of computer servers work together in one or more clusters to manage information and related operations, such as computations, within a distributed or clustered environment. A distributed data grid can be used to manage application objects and data that are shared across the servers. A distributed data grid provides low response time, high throughput, predictable scalability, continuous availability, and information reliability. In particular examples, distributed data grids, such as, e.g., the Oracle Coherence data grid from Oracle Corp., store information in-memory to achieve higher performance, and employ redundancy in keeping copies of that information synchronized across multiple servers, thus ensuring resiliency of the system and continued availability of the data in the event of failure of a server.

In one embodiment, IDCS implements a distributed data grid such as Coherence so that every microservice can request access to shared cache objects without getting blocked. Coherence is a proprietary Java-based in-memory data grid, designed to have better reliability, scalability, and performance than traditional relational database management systems. Coherence provides a peer to peer (i.e., with no central manager), in-memory, distributed cache.

FIG. 12 illustrates an example of a distributed data grid 1200 which stores data and provides data access to clients 1250 and implements embodiments of the invention. A “data grid cluster”, or “distributed data grid”, is a system comprising a plurality of computer servers (e.g., 1220 a, 1220 b, 1220 c, and 1220 d) which work together in one or more clusters (e.g., 1200 a, 1200 b, 1200 c) to store and manage information and related operations, such as computations, within a distributed or clustered environment. While distributed data grid 1200 is illustrated as comprising four servers 1220 a, 1220 b, 1220 c, 1220 d, with five data nodes 1230 a, 1230 b, 1230 c, 1230 d, and 1230 e in a cluster 1200 a, the distributed data grid 1200 may comprise any number of clusters and any number of servers and/or nodes in each cluster. In an embodiment, distributed data grid 1200 implements the present invention.

As illustrated in FIG. 12, a distributed data grid provides data storage and management capabilities by distributing data over a number of servers (e.g., 1220 a, 1220 b, 1220 c, and 1220 d) working together. Each server of the data grid cluster may be a conventional computer system such as, for example, a “commodity x86” server hardware platform with one to two processor sockets and two to four CPU cores per processor socket. Each server (e.g., 1220 a, 1220 b, 1220 c, and 1220 d) is configured with one or more CPUs, Network Interface Cards (“NIC”), and memory including, for example, a minimum of 4 GB of RAM up to 64 GB of RAM or more. Server 1220 a is illustrated as having CPU 1222 a, Memory 1224 a, and NIC 1226 a (these elements are also present but not shown in the other Servers 1220 b, 1220 c, 1220 d). Optionally, each server may also be provided with flash memory (e.g., SSD 1228 a) to provide spillover storage capacity. When provided, the SSD capacity is preferably ten times the size of the RAM. The servers (e.g., 1220 a, 1220 b, 1220 c, 1220 d) in a data grid cluster 1200 a are connected using high bandwidth NICs (e.g., PCI-X or PCIe) to a high-performance network switch 1220 (for example, gigabit Ethernet or better).

A cluster 1200 a preferably contains a minimum of four physical servers to avoid the possibility of data loss during a failure, but a typical installation has many more servers. Failover and failback are more efficient the more servers that are present in each cluster and the impact of a server failure on a cluster is lessened. To minimize communication time between servers, each data grid cluster is ideally confined to a single switch 1202 which provides single hop communication between servers. A cluster may thus be limited by the number of ports on the switch 1202. A typical cluster will therefore include between 4 and 96 physical servers.

In most Wide Area Network (“WAN”) configurations of a distributed data grid 1200, each data center in the WAN has independent, but interconnected, data grid clusters (e.g., 1200 a, 1200 b, and 1200 c). A WAN may, for example, include many more clusters than shown in FIG. 12. Additionally, by using interconnected but independent clusters (e.g., 1200 a, 1200 b, 1200 c) and/or locating interconnected, but independent, clusters in data centers that are remote from one another, the distributed data grid can secure data and service to clients 1250 against simultaneous loss of all servers in one cluster caused by a natural disaster, fire, flooding, extended power loss, and the like.

One or more nodes (e.g., 1230 a, 1230 b, 1230 c, 1230 d and 1230 e) operate on each server (e.g., 1220 a, 1220 b, 1220 c, 1220 d) of a cluster 1200 a. In a distributed data grid, the nodes may be, for example, software applications, virtual machines, or the like, and the servers may comprise an operating system, hypervisor, or the like (not shown) on which the node operates. In an Oracle Coherence data grid, each node is a Java virtual machine (“JVM”). A number of JVMs/nodes may be provided on each server depending on the CPU processing power and memory available on the server. JVMs/nodes may be added, started, stopped, and deleted as required by the distributed data grid. JVMs that run Oracle Coherence automatically join and cluster when started. JVMs/nodes that join a cluster are called cluster members or cluster nodes.

Each client or server includes a bus or other communication mechanism for communicating information, and a processor coupled to bus for processing information. The processor may be any type of general or specific purpose processor. Each client or server may further include a memory for storing information and instructions to be executed by processor. The memory can be comprised of any combination of random access memory (“RAM”), read only memory (“ROM”), static storage such as a magnetic or optical disk, or any other type of computer readable media. Each client or server may further include a communication device, such as a network interface card, to provide access to a network. Therefore, a user may interface with each client or server directly, or remotely through a network, or any other method.

Computer readable media may be any available media that can be accessed by processor and includes both volatile and non-volatile media, removable and non-removable media, and communication media. Communication media may include computer readable instructions, data structures, program modules, or other data in a modulated data signal such as a carrier wave or other transport mechanism, and includes any information delivery media.

The processor may further be coupled via bus to a display, such as a Liquid Crystal Display (“LCD”). A keyboard and a cursor control device, such as a computer mouse, may be further coupled to bus to enable a user to interface with each client or server.

In one embodiment, the memory stores software modules that provide functionality when executed by the processor. The modules include an operating system that provides operating system functionality each client or server. The modules may further include a cloud identity management module for providing cloud identity management functionality, and all other functionality disclosed herein.

The clients may access a web service such as a cloud service. The web service may be implemented on a WebLogic Server from Oracle Corp. in one embodiment. In other embodiments, other implementations of a web service can be used. The web service accesses a database which stores cloud data.

As disclosed, embodiments implement a microservices based architecture to provide cloud-based multi-tenant IAM services. In one embodiment, each requested identity management service is broken into real-time tasks that are handled by a microservice in the middle tier, and near-real-time tasks that are offloaded to a message queue. Accordingly, embodiments provide a cloud-scale IAM platform.

Caching Framework

In one embodiment, IDCS services in the middle tier are implemented to provide statelessness with eventual consistency, while some data such as key entities, tenant/service configurations, etc., are cached to ensure good runtime performance. Generally, eventual consistency is a consistency model used in distributed computing to achieve high availability that informally guarantees that, if no new updates are made to a given data item, eventually all accesses to that item will return the last updated value. One embodiment provides a caching service that provides live/equal data distribution. The caching service is distributed, highly scalable (e.g., to be able to scale out or scale horizontally), and reliable. For example, in one embodiment, providing equal data distribution refers to having equal number of partitions of data at each one of multiple instances of a cache server so that each cache node holds the same number of partitions. In one embodiment, live data distribution refers to not having down time from an application point of view in the event that a cache node comes up or goes down.

One embodiment implements a global cache for IDCS according to a replicated caching scheme. The global cache implements a global namespace and stores the global static artifacts that IDCS needs to run itself, such as static configurations, settings, connection details, and any other data frequently used by IDCS to run itself. The embodiment also implements one cache per tenant for configuration and long-lived data according to a distributed caching scheme. The embodiment also implements one cache per tenant for short-lived and run-time data according to a distributed caching scheme. In one embodiment, a replicated cache is a clustered fault tolerant cache where data is fully replicated to every member in the cluster. In one embodiment, a distributed (or partitioned) cache is a clustered fault tolerant cache that has linear scalability and where data is distributed (or partitioned) among the members in the cluster.

One embodiment uses a Coherence extend client that uses a service discovery component to fetch the cache server host IP in order to connect to it. In one embodiment, the cache server starts the Coherence process that listens on 9099 port, and the HTTP server starts on 9254 port. In one embodiment, the cache server is a Grizzly HTTP server started on 9254 port. It starts the Coherence process using “com.tangosol.net.DefaultCacheServer” on 9099 port. On the server side, the configuration for the Coherence process is maintained in “cache-srv/ . . . /idcs-cache-server-config.xml” and “cache-srv/ . . . /tangosol-coherence-override.xml”. All other IDCS HTTP services (e.g., Admin, SSO, OAuth, SAML, etc.) are clients to the cache server (e.g., the Coherence server process) and connect to the cache server via TCP. On the client side, the configuration for Coherence extend clients is maintained in “cache/ . . . /idcs-cache-server-config.xml” and “cache/ . . . /tangosol-coherence-override.xml”.

In one embodiment, the cache client connects to the cache as follows. The Coherence server process is started by the cache server at 9099 port. The Coherence extend client needs the IP of the host of the cache server. Client configuration instructs the client how to get the IP of the cache server at run-time as follows:

<address-providers> <address-provider id=“idcs”> <class-factory-name>oracle.idaas.cache.coherence.provider.AddressProviderFactory</class- factory-name> <method-name>provide</method-name> </address-provider> </address-providers>

When the HTTP service starts, a “CacheInitilizer’ initializes an “AddressProviderFactory” which in turn gets the address of the cache server using service discovery (e.g., a Nimbula client), and this IP is handed over to the Coherence extend client, and thus the client connects to the cache server.

Remote API Proxy for Caching Functionality

FIG. 13 is an example block diagram 1300 illustrating caching functionality in IDCS 1320 in one embodiment where a REST client 1302 sends a request to IDCS 1320 (e.g., “/admin/v1/<Resource>/Get”) and receives a JSON response payload in return. In this embodiment, each IDCS microservice 1304 is running its own JVM and has its own near cache 1316 (e.g., for caching static artifacts). Generally, a near cache is a hybrid cache that typically fronts a distributed or remote cache with a local cache, where local caching refers to caching data on clients rather than on servers. The embodiment also implements an in-memory data grid 1306 such as Oracle Coherence for its distributed/remote caching infrastructure. However, other alternative embodiments may implement other caching infrastructures such as memcache, ecache, ehcache, etc. In-memory data grid 1306 includes a number of nodes 1322 and may provide any functionality described herein with reference to distributed data grid 1200 in FIG. 12.

In the embodiment of FIG. 13, a resource manager 1312 (a cache manager or resource provider) is included as a common infrastructure in all IDCS microservices 1304. However, although each microservice 1304 includes a resource manager 1312 that in turn includes a data provider 1314 (e.g., a common interaction library that can interact with a data repository), only the admin microservice may use data provider 1314 to talk to a database 1308 and/or an LDAP 1310 and thereby have connectivity to database 1308 and/or LDAP 1310. Since only the administration microservice (also referred to herein as the administration service, admin service, or admin microservice) is able to open database/LDAP connections, the embodiment prevents random connections to database 1308 and/or LDAP 1310 by various microservices, and thus provides better control of the number of connections established between the middle tier and database 1308 and/or LDAP 1310. In some embodiments, a microservice other than the administration microservice (e.g., job) may also be allowed to use the functionality of data provider 1314 to connect to database 1308 and/or LDAP 1310 to obtain some resources. However, the common resources (the resources that can be used by all microservices, such as settings, global configuration, notification configuration, etc.) can only be accessed by the administration microservice.

In one embodiment, when data is accessed via data provider 1314 sitting on the administration microservice and a resource is pulled from database 1308 or LDAP 1310, the accessed data is cached in near cache 1316 or remote cache 1306 and thus the cache gets wound up. In one embodiment, either one or both of the administration microservice and the microservice that contacted the administration microservice may cache the accessed data. In one embodiment, the accessed data is cached in near cache 1316 in the JVM of the requesting microservice. In one embodiment, when a resource is requested, the administration microservice makes a call (e.g., “cache.get”) to obtain the resource.

In one embodiment, when microservice 1304 contacts the admin service and receives a resource in response, microservice 1304 looks up configuration information corresponding to the resource and determines whether the resource is cachable or not, and if cachable, whether it is configured to be near cached or remote cached. If the resource is cachable and configured to be near cached, microservice 1304 caches the received resource in near cache 1316. If the resource is cachable and configured to be remote cached, microservice 1304 caches the received resource in remote cache 1306.

In one embodiment, when REST client 1302 makes a request to IDCS 1320, the request is routed to a corresponding IDCS microservice 1304 in the middle tier. If an IDCS microservice 1304 other than the admin service (e.g., SSO, SAML, OAuth, etc.) receives a request for a resource (e.g., an OAuth client, an OAuth resource, a user, a group, etc.), microservice 1304 would incur network latency if it calls the admin service even if the resource is already in near cache 1316 and/or remote cache 1306. If microservice 1304 calls the IDCS admin service to obtain the resource, the admin service calls its resource manager 1312. Resource manager 1312 of the admin service talks to different data providers 1314 to reach different data repositories. In one embodiment, the data providers include a cache data provider to interact with a cache.

In one embodiment, when resource manager 1312 of the admin service is called for data, it first talks to the cache data provider. The cache data provider looks into cached data in near cache 1316 of the admin service and/or remote cache 1306 and returns the data if it is cached in near cache 1316 and/or remote cache 1306 (i.e., a cache hit). If the cache data provider does not find cached data (i.e., a cache miss), it goes to another data provider such as Java Database Connectivity (“JDBC”) for reaching database 1308 or Java Naming and Directory Interface (“JNDI”) for reaching LDAP 1310. Such data providers use network calls to reach their respective repositories, and may therefore cause latency due to the incurred network hop. Moreover, calling the admin service for every resource request may flood the admin service.

However, in order to avoid the network latency incurred by repeatedly calling the admin service (especially for runtime services such as OAuth, SAML, and SSO), one embodiment implements a remote API proxy 1318 on each IDCS microservice 1304 (except for the admin service). In one embodiment, remote API proxy 1318 is a plugin that sits on each microservice 1304 and can directly interact with near cache 1316 in microservice 1304 and/or remote cache 1306. Accordingly, if a requested resource is cached in near cache 1316 and/or remote cache 1306, microservice 1304 does not need to call the admin service to obtain that resource, and instead calls remote API proxy 1318 that fetches the cached resource. If the resource is not cached in near cache 1316 and/or remote cache 1306, then microservice 1304 calls the admin service to obtain the resource. Therefore, microservice 1304 does not need to call the admin service every time a resource is needed, and database 1308 or LDAP 1310 do not need to be hit for every request.

FIG. 14 is an example block diagram 1400 illustrating the functionality of a remote API proxy 1404 in one embodiment. In one embodiment, remote API proxy 1404 is consumed by (i.e., implemented in) all microservices other than the administration microservice. When a microservice 1402 (e.g., an OAuth, SSO, or SAML configuration) receives a request for a resource, its remote API proxy 1404 implements metadata driven functionality and determines whether the resource is cachable. Based on the metadata of the requested resource, if the resource is indicated as cachable, remote API proxy 1404 looks into a near cache 1410 in the same JVM as microservice 1402, and if it does not find the resource in near cache 1410, it establishes a connection with a remote cache 1412 and looks into remote cache 1412. If it does not find the data in remote cache 1412 either, then it makes a call to the IDCS admin service 1414. Accordingly, less number of threads are needed for admin service 1414, and fewer calls are made to admin service 1414, thus preventing admin service 1414 from getting flooded. Further, fewer network calls are made to data repositories, thus reducing latencies.

Generally, an API proxy emulates the functionality of an API. In one embodiment, remote API proxy 1404 emulates the functionality of admin service 1414, and such emulation is transparent to microservice 1402 that requests a resource. In one embodiment, remote API proxy 1404 emulates the functionality of admin service 1414 by using the same cache interfaces and calling the same APIs called by admin service 1414.

In one embodiment, remote API proxy 1404 implements a “RemoteAPIProxyFactory” Java class 1406 and a “RemoteAPIProxySCIMService” Java class 1408. In one embodiment, a Java code of microservice 1402 instantiates “RemoteAPIProxyFactory” 1406 to get a handle to “RemoteAPIProxySCIMService” 1408. In one embodiment, for example, there may be three resources: OAuth configuration, OAuth settings, and SSO settings, where the three resources have three different SCIM services. In this embodiment, “RemoteAPIProxyFactory” 1406 is a singleton Java class that is used to get to those different SCIM services (i.e., “RemoteAPIProxySCIMService” 1408), which in turn implement various cache access functionality by accessing near cache 1410, remote cache 1412, or administration microservice 1414 as described herein.

FIG. 15 is an example block diagram 1500 illustrating code categorization for caching functionality in one embodiment that implements both API and Service Provider Interface (“SPI”) functionality. Generally, an SPI is an API intended to be implemented or extended by a third-party. An SPI may be used to enable framework extension and replaceable components. In this embodiment, a cache API 1510 sits in a common module 1506 available to all microservices 1502, while an SPI 1508 such as a Coherence SPI sits in a cache module 1504 and provides functionality to connect to a remote cache such as Coherence. Accordingly, common module 1506 provides interface functionality (i.e., cache API 1510) for using cache functionality (i.e., Coherence SPI 1508) implemented by cache module 1504.

In one embodiment, cache module 1504 provides all the functionality for interfacing with Coherence, such as connectivity, making Coherence API calls, etc. In one embodiment, remote API proxy functionality is included in common module 1506 provided to each microservice 1502. The remote API proxy of microservice 1502 may make cache calls via cache API 1510 in common module 1506. As such, common module 1506 provides an interface between the remote cache and other components of IDCS. Depending on their needs, a microservice 1502 may instantiate a process using cache API 1510 in common module 1506, but if a microservice does not need to use the remote cache, they do not need to consume cache module 1504.

In one embodiment, microservice 1502 has compile time dependency on common module 1506 and run-time dependency on cache module 1504, while cache module 1504 has compile time dependency on common module 1506. Accordingly, if the remote cache implementation needs to be changed (e.g., from Coherence to memcache), common module 1506 does not need to be changed.

FIG. 16 is an example block diagram 1600 illustrating a deployment view of IDCS according to an embodiment. In this embodiment, a middle tier cluster 1602 implements the IDCS middle tier which includes two sub-tiers: a platform tier that includes IDCS platform microservices 1604 and an infrastructure tier that includes IDCS infrastructure microservices 1606. In one embodiment, middle tier cluster 1602 is a compute node that provides resources that can be consumed by virtual machine instances. In one embodiment, a compute node is identified by an IP address where a Java process is running. In one embodiment, a compute node provides a JVM on which a service is deployed. A compute node may be located at one of multiple data centers that implement the embodiments. In one embodiment, middle tier cluster 1602 includes platform service managers 1608 and infrastructure service managers 1610 which provide resource manager functionality (e.g., to call a cache service to fetch cached data) for a respective platform microservice 1604 or infrastructure microservice 1606.

Each microservice has cache intelligence on other tiers by implementing either a cache data provider (e.g., for the admin microservice) or a remote API proxy (e.g., for services other than the admin microservice). Each microservice can talk to a distributed cache service 1614 in a caching cluster 1612 via a cache data provider or a remote API proxy. In one embodiment, caching cluster 1612 is a centralized caching cluster implemented as a compute node. Depending on the data needed by the microservices, distributed cache service 1614 communicates with an information model 1618 in a data access tier 1616. In one embodiment, information model 1618 refers to eXtensible Markup Language (“XML”) metadata information stored at caching cluster 1612 and providing a representation of concepts and the relationships, constraints, rules, and operations to specify data semantics for, e.g., configuration, objects, transactional data. Information model 1618 may in turn communicate with metadata stores 1624 in a Schema as a Service (“SaaS”) cluster 1622 (e.g., implemented by an Oracle “Exadata” database machine from Oracle Corp.) that implements a data repository tier. In one embodiment, data access tier 1616 includes data access services 1620 that implement various data providers (e.g., LDAP data provider, etc.).

In one embodiment, cache service 1614 implements a Coherence server from Oracle Corp. In one embodiment, the microservices in the middle tier communicate with each other over HTTP, while each microservice can communicate with cache service 1614 in caching cluster 1612 by making cache API calls or Coherence calls to establish a TCP connection.

In one embodiment, IDCS further provides a caching microservice 1626 as an infrastructure microservice. When IDCS receives a request for a resource from a client (e.g., a REST client), caching microservice 1626 starts a corresponding process. When caching microservice 1626 is started, a Coherence server is also started within distributed cache service 1614 to provide remote cache functionality and hold data. In one embodiment, if the requested resource is not available in a local cache of a respective microservice, the remote cache provided by distributed cache service 1614 is reached.

In one embodiment, the microservices in the middle tier are “loosely coupled”, meaning they are not wired in a way that starting/stopping one microservice will cause starting/stopping another microservice, and each microservice can go down in an isolated fashion from a life cycle management (“LCM”) point of view. In one embodiment, the various microservices are sitting on an HTTP server such as Grizzly.

In one embodiment, caching microservices 1626 talk to Coherence in a standalone manner. Generally, Coherence may be deployed in various configurations, and this embodiment implements Coherence in a standalone configuration, meaning that a number of virtual machines can start a standalone cache server or Coherence server and form a cluster. In one embodiment, multiple caching microservices 1626 correspond to multiple instances of the cache server, each starting one Coherence server, and the Coherence servers together form a cluster. The resulting cache cluster is not tightly coupled with the IDCS microservices from an LCM point of view, and the virtual machines in the cache cluster can go down and come up without affecting the microservices in the middle tier. In one embodiment, the microservices are loosely coupled with the cache cluster (or distributed grid), and they talk to the cluster over HTTP or TCP depending on the operation to be performed (e.g., HTTP to obtain cache status and TCP to fetch data).

Metadata Driven Functionality for Caching Service

One embodiment implements metadata driven functionality to statically indicate cachability configuration of each resource in a file (e.g., a JSON file), for example, whether each resource is cachable or not. Accordingly, there is no code change required to indicate cachability configuration of a resource, and a consumer of IDCS does not need to implement any category reference or hard coded reference that indicates whether a subject/resource is cachable. In one embodiment, the caching layer in IDCS does not need to have a static reference (a well-known key of a cached object) to find a resource or to determine whether the resource us cachable or not. One embodiment further provides metadata-driven searching functionality in cache by determining composite keys based on metadata. The embodiment allows for declaratively searching unique records based on composite keys.

Generally, HTTP may be used to transmit files and/or “resources,” where a resource may be the target of a certain URL (e.g., a file, a query result, etc.). In one embodiment, every resource has a resource type associated with it, and the resource type is described in metadata of the resource definition. The resource definition is understandable to the IDCS resource manager or some other internal IDCS components.

One embodiment augments the resource definition with additional metadata so that the caching layers (e.g., a cache data provider and/or a remote API proxy) understand the additional metadata and can use it to determine if a resource is cachable or not. As such, when a consumer indicates that they need to access a resource, the caching layer, while being agnostic to any static reference to any particular resource, may examine the metadata and determine if the resource is cachable, and then examine a near and/or remote cache accordingly.

In one embodiment, when a resource is introduced into IDCS, a corresponding resource owner knows the access pattern to this particular resource from an implementation point of view (e.g., is it a frequently accessed resource, is it a frequently modifiable resource, whether the data is per tenant or global, etc.). In one embodiment, such access pattern also indicates whether the resource is to be cached or not and what will be the cache keys (e.g., the identifiers that can be used to retrieve the cached data). In one embodiment, such access pattern in indicated in a resource type definition of the resource. In one embodiment, a resource type definition of each resource is a JSON file held at the global database of IDCS and indicates resource specific information such as what the resource is, what are the corresponding endpoint and provider, what operations are supported, etc. In one embodiment, the JSON file also indicates whether a resource is cachable (e.g., via a flag). When a resource is cachable, further metadata information (e.g., another flag) may indicate whether the resource is remote cached (i.e., cached in a JVM other than the service) or near cached.

In one embodiment, the resource manager examines the resource metadata, and if the resource is cachable, the resource manager instantiates a cache data provider for that resource. In one embodiment, a cache data provider is instantiated per every request on the administration microservice for a resource. One embodiment determines whether a resource is cachable or not, and whether it is near cached or remote cached. For example, in one embodiment, SSO configuration is a resource for the SSO microservice and is configured as cachable in near cache, while a password policy is a tenant specific resource that is configured as cachable in remote cache.

In one embodiment, when a resource is cached on the near cache of a JVM, the memory size of the JVM goes up. Accordingly, one embodiment prevents the memory size of a JVM to grow exponentially by caching runtime data in the remote cache and not in the near cache. In one embodiment, when the number of a certain resource is not known or controllable, such resource is configured as not cachable or as remote cached. For example, users or groups in a system or other tenant specific resources (e.g., applications) that may be dynamically added by a tenant administrator may be configured as remote cached. In contrast, global resources (e.g., non-tenant-specific resources that are accessed across IDCS) and highly used resources (e.g., resources required for login/logout) do not grow exponentially and are configured as cachable in the near cache.

In one embodiment, cache configuration in a resource-type JSON file of SCIM resources determines if an object is cacheable or not and in which cache the object will reside. The following functionality provides an example of implementing this configuration.

″cachePostProcess″: true ″resourcesManaged“ - determines if resource is tenant specific or global ″cache″: { ″cacheable″: true, // if resource is cacheable or NOT ″type″: ″tenant-near″, // if resource will reside in remote cache or near cache.  ″compositeKeys″: [ // composite Key for searching unique record ″keyStoreId, sha1Thumbprint, type″, ″keyStoreId, sha256Thumbprint, type″, ″keyStoreId, certificateAlias, type″ ] }

In one embodiment, the “type” parameter in the above functionality is interpreted as follows: an object indicated as “lasting” is a tenant specific global object that does not change frequently, an object indicated as “transient” is a tenant specific run-time object that changes frequently, and an object indicated as “tenant-near” is a tenant-specific object that needs to be near cached.

In one embodiment, the following caches are provided for storing different objects:

A cache for tenant specific configuration objects: Objects marked as “lasting” reside here (name of the namespace: IDCSTConfig_<tenantName>).

A cache for tenant specific run time objects: Objects that are not marked as lasting reside here (name of the namespace: IDCSTRuntime_<tenantName>).

A cache for global artifacts (non-tenant specific or for Oracle tenant): Irrespective of being marked as “lasting” or not, non-tenant objects that need to be cached reside here (name of the namespace: IDCSGlobalConfig).

Caches for storing Plain Old Java Objects (“POJOs”) such as keys and authorization policy and having their own name spaces:

IDCSPOJO_<tenantName>_Keys and IDCSPOJO_<tenantName>_AuthorizationPolicyCache

In one embodiment, these caches are configured such that the cached are in the same JVM (near cached) or in a remote JVM (distributed cached), and the configuration contracts are in XMLs as follows:

-   -   tangosol-coherence-override.xml: the contract between coherence         and up-taking application     -   configurable-cache-factory-config: defining caching schemes         (near-scheme or remote-cache-scheme) and associating them with         caches     -   near caches: global configuration, POJO keys, and POJO         authorization policy     -   remote caches: e.g., tenant specific objects except those of         type “tenant-near”

Multi-Tenant Caching Framework

One embodiment provides a caching framework that supports multi-tenancy. In one embodiment, no two tenants have their data residing at the same namespace on the cache. Generally, a namespace is a set of symbols that are used to organize objects of various kinds so that these objects may be referred to by name. When an object is stored in a cache, the namespace provides a map that can be used to find the object. In one embodiment, each tenant has its own map/namespace for locating their objects (e.g., resources). In one embodiment, when a new tenant is added in a runtime operation, a corresponding tenant specific namespace is implemented to support caching functionality for that tenant. Accordingly, even if data of different tenants are stored in the same database, implementing tenant specific namespaces ensures separation of the data of different tenants, and thus supports multi-tenancy.

In one embodiment, implementing tenant specific namespaces provides better data security by preventing one tenant from accidentally or deliberately accessing another tenant's data. Further, implementing tenant specific namespaces may provide better performance when different tenants have different amounts of data. For example, if a same namespace is used for two tenants, one with a large amount of data and one with a small amount of data, both tenants may experience the same level of performance when accessing cached data. However, when separate tenant specific namespaces are used for these two tenants, the cache access performance of the tenant with less data is not hindered because of the large amount of data of the other tenant.

FIG. 17 is a flow diagram 1700 of the operation of IAM functionality in accordance with an embodiment. In one embodiment, the functionality of the flow diagram of FIG. 17 is implemented by software stored in memory or other computer readable or tangible medium, and executed by a processor. In other embodiments, the functionality may be performed by hardware (e.g., through the use of an application specific integrated circuit (“ASIC”), a programmable gate array (“PGA”), a field programmable gate array (“FPGA”), etc.), or any combination of hardware and software.

At 1702 a request is received from a client for a resource, at 1704 the request is authenticated, and at 1706 a microservice is accessed based on the request. For example, in one embodiment, a variety of applications/services 602 may make HTTP calls to IDCS APIs to use IDCS microservices 614 as illustrated in FIG. 6 and as described herein with reference to the IDCS “API platform” and accessing microservices in IDCS middle tier 614 in FIG. 6. In one embodiment, the microservice is a self-contained module that can communicate with other modules/microservices, and each microservice has an unnamed universal port that can be contacted by others. In one embodiment, the request is authenticated by a security gate such as Cloud Gate as described herein, for example, with reference to web routing tier 610 in FIG. 6 and/or cloud gate 702 in FIG. 7.

At 1708 the microservice determines whether the resource is cached in a near cache or in a remote cache, at 1710 the resource is retrieved from the near cache or from the remote cache when the resource is cached, and at 1712 an administration microservice is called to obtain the resource when the resource is not cached, for example, as described herein with reference to FIGS. 13 and 14.

At 1714 the resource is provided to the client. In one embodiment, the request includes an HTTP request, the client includes a REST client, the administration microservice includes a SCIM microservice, and the providing includes sending a JSON response payload. In one embodiment, the microservice is stateless, the remote cache includes a distributed data grid, and the remote cache and the microservice are configured to scale independently of one another. In one embodiment, the near cache is implemented in a virtual machine that implements the microservice.

In one embodiment, the microservice obtains the resource by calling a remote API proxy implemented in the virtual machine that implements the microservice. In one embodiment, the microservice is not an administration microservice, and the remote API proxy emulates the functionality of the administration microservice. In one embodiment, the remote API proxy determines whether the resource is cachable or not, and when the resource is cachable, whether the resource is configured to be cached in the near cache or in the remote cache. In one embodiment, the remote API proxy looks for the resource in the near cache when the resource is cachable and configured to be cached in the near cache. In one embodiment, the remote API proxy looks for the resource in the remote cache when the resource is cachable and configured to be cached in the remote cache. In one embodiment, the remote API proxy calls the administration microservice to obtain the resource if the resource is not cachable or if the resource is cachable but is not cached in the near cache or in the remote cache.

In one embodiment, the resource is configured to be cached in the near cache when the resource is not a tenant specific resource. In one embodiment, a file stored at a global database indicates whether the resource is cachable, and if cachable, whether the resource is configured to be cached in the remote cache or in the near cache. In one embodiment, the resource is configured to be cached in the remote cache when the resource is a tenant specific resource. In one embodiment, the remote cache implements a different namespace for each tenant that uses the microservice.

As disclosed, embodiments implement stateless microservices that provide cloud-based multi-tenant IAM services, and provide a caching framework that supports the stateless microservices. The caching framework implements a near cache in the virtual machine of each microservice, as well as a remote cache provided by a distributed data grid. In one embodiment, a remote API proxy is implemented in each microservice except for an administration microservice, and emulates the administration microservice to allow microservices to retrieve cached data without needing to call the administration microservice every time a resource is requested. Accordingly, embodiments remove the network hops needed to reach the administration service, reduce the load on the administration service, and improve performance.

Several embodiments are specifically illustrated and/or described herein. However, it will be appreciated that modifications and variations of the disclosed embodiments are covered by the above teachings and within the purview of the appended claims without departing from the spirit and intended scope of the invention. 

What is claimed is:
 1. A caching framework for a multi-tenant cloud-based system comprising: a plurality of microservices; a global cache that implements a global namespace; a plurality of tenant caches, each tenant cache corresponding to a different tenant of the multi-tenant cloud-based system; a common module corresponding to each of the microservices and comprising a cache application programming interface (API); and a cache module comprising a service provider interface (SPI) adapted to connect to a distributed remote cache.
 2. The caching framework of claim 1, wherein the remote cache comprises an in-memory data grid.
 3. The caching framework of claim 2, wherein the in-memory data grid comprises Coherence.
 4. The caching framework of claim 1, wherein each of the different tenants has a separate corresponding namespace for finding objects located in cache.
 5. The caching framework of claim 1, wherein the common module comprises a remote API proxy.
 6. The caching framework of claim 5, further comprising one or more processors adapted to: receive a request from a client for a resource, the request comprising a call to a first cache API that identifies a first microservice, the resource comprising metadata; authenticate the request; access the first microservice of the plurality of microservices based on the request, the first microservice comprising the remote API proxy and a near cache, wherein the near cache is local to the first microservice and fronts a remote cache; determine, by the remote API proxy, whether the resource is indicated as cacheable based on the metadata, and if cacheable whether the resource is cached in the near cache or in the remote cache, wherein the remote cache is external of the first microservice and the remote API proxy establishes a connection with the remote cache; in response to determining the resource is indicated as cacheable in the near cache, retrieve the resource from the near cache or from the remote cache when the resource is cached; call an administration microservice to obtain the resource when the resource is not cached, wherein the administration microservice is a different microservice than the first microservice; and provide the resource to the client.
 7. The caching framework of claim 6, wherein the administration microservice obtains the resource from a connection to a database or a connection to a Lightweight Directory Access Protocol (LDAP).
 8. The caching framework of claim 6, wherein the request comprises a Hypertext Transfer Protocol (HTTP) request, wherein the client comprises a Representational State Transfer (REST) client, wherein the administration microservice comprises a System for Cross-domain Identity Management (SCIM) microservice, wherein the providing comprises sending a JavaScript Object Notation (JSON) response payload.
 9. The caching framework of claim 1, wherein each microservice has compile time dependency on its respective common module and has run time dependency on the cache module.
 10. A computer readable medium having instructions stored thereon that, when executed by one or more processors, cause the processors to implement a caching framework for a multi-tenant cloud-based system, the caching framework comprising: a plurality of microservices; a global cache that implements a global namespace; a plurality of tenant caches, each tenant cache corresponding to a different tenant of the multi-tenant cloud-based system; a common module corresponding to each of the microservices and comprising a cache application programming interface (API); and a cache module comprising a service provider interface (SPI) adapted to connect to a distributed remote cache.
 11. The computer readable medium of claim 10, wherein the remote cache comprises an in-memory data grid.
 12. The computer readable medium of claim 11, wherein the in-memory data grid comprises Coherence.
 13. The computer readable medium of claim 10, wherein each of the different tenants has a separate corresponding namespace for finding objects located in cache.
 14. The computer readable medium of claim 10, wherein the common module comprises a remote API proxy.
 15. The computer readable medium of claim 14, the caching framework further comprising: receiving a request from a client for a resource, the request comprising a call to a first cache API that identifies a first microservice, the resource comprising metadata; authenticating the request; accessing the first microservice of the plurality of microservices based on the request, the first microservice comprising the remote API proxy and a near cache, wherein the near cache is local to the first microservice and fronts a remote cache; determining, by the remote API proxy, whether the resource is indicated as cacheable based on the metadata, and if cacheable whether the resource is cached in the near cache or in the remote cache, wherein the remote cache is external of the first microservice and the remote API proxy establishes a connection with the remote cache; in response to determining the resource is indicated as cacheable in the near cache, retrieving the resource from the near cache or from the remote cache when the resource is cached; calling an administration microservice to obtain the resource when the resource is not cached, wherein the administration microservice is a different microservice than the first microservice; and providing the resource to the client.
 16. The computer readable medium of claim 15, wherein the administration microservice obtains the resource from a connection to a database or a connection to a Lightweight Directory Access Protocol (LDAP).
 17. The computer readable medium of claim 15, wherein the request comprises a Hypertext Transfer Protocol (HTTP) request, wherein the client comprises a Representational State Transfer (REST) client, wherein the administration microservice comprises a System for Cross-domain Identity Management (SCIM) microservice, wherein the providing comprises sending a JavaScript Object Notation (JSON) response payload.
 18. The computer readable medium of claim 10, wherein each microservice has compile time dependency on its respective common module and has run time dependency on the cache module.
 19. A method of providing a caching framework for a multi-tenant cloud-based system comprising: generating a plurality of microservices, each of the microservices having access to a global cache that implements a global namespace and a plurality of tenant caches, each tenant cache corresponding to a different tenant of the multi-tenant cloud-based system; generating a common module corresponding to each of the microservices and comprising a cache application programming interface (API); and generating a cache module comprising a service provider interface (SPI) adapted to connect to a distributed remote cache.
 20. The method of claim 19, wherein the remote cache comprises an in-memory data grid. 